The Cucumber Book

Transcription

The Cucumber Book
www.it-ebooks.info
What Readers Are Saying About
The Cucumber Book
Few tools have managed to bridge the developer-customer divide as well as
Cucumber has. Cucumber is not a tool for testing applications. Cucumber is a
philosophy for communicating requirements. This book brings that philosophy
to life.
➤ Robert C. Martin (Uncle Bob)
I devoured the Cucumber book on a train ride from Grenoble to Brussels a few
days after watching Matt’s presentation “BDD As It’s Meant to Be Done.” These
two resources helped me understand in just a few hours how to avoid dozens of
common mistakes writing scenarios in the Cucumber style. It’s as though I received
an injection of perhaps two years of experience writing scenarios poorly so that I
didn’t have to go through it all myself. What a gift. I recommend this book to
everyone working with Cucumber.
➤ J. B. Rainsberger
Author, JUnit Recipes
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Teams can use Cucumber to get a better understanding of what software to build
for their customers. In this book, Aslak and Matt do a brilliant job explaining how
you get started with Cucumber with plenty of easy-to-follow examples.
➤ Rachel Davies
Author, Agile Coaching
To those of you wondering how to use Cucumber effectively, The Cucumber Book
is the answer. Not content to write just a testing book, Aslak and Matt have packed
it with practical insights on many aspects of software development. Studying this
book will make you a better software developer.
➤ Pat Maddox, B.D.D.M.F.
RSpec Core team
This is a much-needed book, providing not only an expanded description of how
to use Cucumber but an opinionated one to suggest how to use it for the best effect.
Reading this book is like having Aslak and Matt sitting next to you, patiently
helping you through your first project with Cucumber. Not only will you learn
effective use of Cucumber, but you’ll also be introduced to several other Ruby
tools that can be used with Cucumber.
➤ George Dinwiddie
Software development coach at iDIA Computing, LLC
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Matt and Aslak show you how Cucumber can save you from stale documentation,
unclear requirements, and absentee tests. By the end of the book, your team’s
programmers, testers, and product owners will be talking excitedly about the next
great product you’re going to build together.
➤ Ian Dees
Author, Scripted GUI Testing with Ruby
This book had me at “Cucumber is designed to help build bridges between the
technical and nontechnical members of a software team.” Wynne and Hellesøy
understand the whole-team approach to specification by example, with diverse
team members collaborating to deliver what the customer really wants. They use
examples to teach us how to automate regression checks with Cucumber, use it
to build a safety net to allow refactoring, and free testers to contribute their most
valuable skills to the team.
➤ Lisa Crispin
Author, Agile Testing: A Practical Guide for Testers (with Janet Gregory)
This book is a tale of how to do effective acceptance testing, with Cucumber as
the filling in the sandwich. The authors don’t just scratch the surface; they get
right under the skin and show us how versatile Cucumber can be.
➤ Robert Chatley
Principal, Devlogical
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Lots of great tips for Cucumber newbies and experts alike—Matt and Aslak have
done a great job of explaining everything from getting started to how to get the
most out of Cucumber. You’ll want to read this book cover to cover and keep it
close as a reference!
➤ Gojko Adzic
Author, Specification by Example and Bridging the Communication Gap
The Cucumber Book is a must-read for anyone thinking about using Cucumber;
it is scattered with treasures for even the most experienced Cucumber users.
➤ Antony Marcano
RiverGlide
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The Cucumber Book
Behaviour-Driven Development
for Testers and Developers
Matt Wynne
Aslak Hellesøy
The Pragmatic Bookshelf
Dallas, Texas • Raleigh, North Carolina
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Many of the designations used by manufacturers and sellers to distinguish their products
are claimed as trademarks. Where those designations appear in this book, and The Pragmatic
Programmers, LLC was aware of a trademark claim, the designations have been printed in
initial capital letters or in all capitals. The Pragmatic Starter Kit, The Pragmatic Programmer,
Pragmatic Programming, Pragmatic Bookshelf, PragProg and the linking g device are trademarks of The Pragmatic Programmers, LLC.
Every precaution was taken in the preparation of this book. However, the publisher assumes
no responsibility for errors or omissions, or for damages that may result from the use of
information (including program listings) contained herein.
Our Pragmatic courses, workshops, and other products can help you and your team create
better software and have more fun. For more information, as well as the latest Pragmatic
titles, please visit us at http://pragprog.com.
The team that produced this book includes:
Jackie Carter (editor)
Potomac Indexing, LLC (indexer)
Kim Wimpsett (copyeditor)
David J Kelly (typesetter)
Janet Furlow (producer)
Juliet Benda (rights)
Ellie Callahan (support)
Copyright © 2012 Pragmatic Programmers, LLC.
All rights reserved.
No part of this publication may be reproduced, stored in a retrieval system, or
transmitted, in any form, or by any means, electronic, mechanical, photocopying,
recording, or otherwise, without the prior consent of the publisher.
Printed in the United States of America.
ISBN-13: 978-1-934356-80-7
Printed on acid-free paper.
Book version: P1.0—January 2012
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Contents
Foreword
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Acknowledgments
Preface .
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Part I — Cucumber Fundamentals
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Why
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Cucumber? .
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Automated Acceptance Tests
Behaviour-Driven Development
Living Documentation
How Cucumber Works
What We Just Learned
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First
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Taste .
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Understanding Our Goal
Creating a Feature
Creating Step Definitions
Implementing Our First Step Definition
Running Our Program
Changing Formatters
Adding an Assertion
Making It Pass
What We Just Learned
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Gherkin Basics .
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3.1 What’s Gherkin For?
3.2 Format and Syntax
3.3 Feature
3.4 Scenario
3.5 Comments
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Spoken languages
What We Just Learned
Definitions: From the Outside
Steps and Step Definitions
Capturing Arguments
Multiple Captures
Flexibility
Returning Results
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Step
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Expressive Scenarios
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5.1 Background
5.2 Data Tables
5.3 Scenario Outline
5.4 Nesting Steps
5.5 Doc Strings
5.6 Staying Organized with Tags and Subfolders
5.7 What We Just Learned
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When Cucumbers Go Bad
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6.1 Feeling the Pain
6.2 Working Together
6.3 Caring for Your Tests
6.4 Stop the Line and Defect Prevention
6.5 What We Just Learned
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Part II — A Worked Example
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Definitions: On the Inside .
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Sketching Out the Domain Model
Removing Duplication with Transforms
Adding Custom Helper Methods to the World
Organizing the Code
What We Just Learned
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8.1 Fixing the Bug
8.2 Bootstrapping the User Interface
8.3 Making the Switch
8.4 Using Hooks
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Building the User Interface
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Dealing with Message Queues and Asynchronous
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9.1 Our New Asynchronous Architecture
9.2 How to Synchronize
9.3 Implementing the New Architecture
9.4 Fixing the Flickering Scenario
9.5 What We Just Learned
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11. The Cucumber Command-Line Interface
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11.1 Cucumber’s Command-Line Options
11.2 Running a Subset of Scenarios
11.3 Changing Cucumber’s Output
11.4 Specifying the Location of Step Definitions
11.5 Managing Your Work in Progress (WIP)
11.6 Using Profiles
11.7 Running Cucumber from Rake
11.8 Running Cucumber in Continuous Integration
11.9 What We Just Learned
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12. Testing a REST Web Service
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12.1 In-Process Testing of Rack-Based REST APIs
12.2 Out-of-Process Testing of Any REST API
12.3 What We Just Learned
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13. Adding Tests to a Legacy Application
13.1 Characterization Tests
13.2 Squashing Bugs
13.3 Adding New Behavior
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10. Databases .
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10.1 Introducing ActiveRecord
10.2 Refactoring to Use a Database
10.3 Reading and Writing to the Database
10.4 Cleaning the Database with Transactions
10.5 Cleaning the Database with Truncation
10.6 What We Just Learned
Part III — Cucumber Applied
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13.4 Code Coverage
13.5 What We Just Learned
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14. Bootstrapping Rails
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14.1 Running the Generators
14.2 Creating a User
14.3 Posting a Message
14.4 Associating a Message with a User
14.5 Creating a Controller by Hand
14.6 Implementing the View
14.7 What We Just Learned
14.8 Try this
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15. Using Capybara to Test Ajax Web Applications .
15.1 Implementing a Simple Search Without Ajax
15.2 Searching with Ajax
15.3 The Capybara API
15.4 Taking Screenshots
15.5 What We Just Learned
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16. Testing Command-Line Applications with Aruba
16.1 Simple Interfaces
16.2 Our First Aruba Feature
16.3 Working with Files and Executables
16.4 Interacting with User Input
16.5 Using Aruba’s Ruby DSL
16.6 What We Just Learned
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A1. Using Cucumber with Other Platforms
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A2. Installing Cucumber
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A2.1 Installing Ruby
A2.2 HTTP Proxy Settings
A2.3 Installing Bundler
A2.4 Installing Cucumber (and RSpec)
A2.5 Installing Other Gems
A2.6 Choosing a Text Editor
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A3. Ruby Gem Versions
A4. Bibliography
Index
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Foreword
Behaviour-driven development has come a long way since I first started
talking about it in 2003. At that time, I was simply trying to find better ways
to explain the revelatory practice of TDD, usually to nervous, suspicious, or
at the very least skeptical programmers. Why would you write tests ahead of
any code? That didn’t make sense. And why were we writing tests anyway—
don’t we have testers for that?
Very few things represent a genuine paradigm shift. Mostly the term is used
by marketers to convince you to change your brand of toothpaste. According
to the Free Online Dictionary, a paradigm1 is “A set of assumptions, concepts,
values, and practices that constitutes a way of viewing reality for the community that shares them.” That’s right, a paradigm shift involves messing with
someone’s sense of reality! No wonder they get uncomfortable.
TDD is one of those rare genuine cases, so it’s no surprise that many people
are deeply skeptical when you start trying to introduce it. And it’s also not
surprising that it took us several attempts at articulating it, in different ways,
from different angles, and with different audiences, before we found something
that worked. At first we started deep in the code, because that’s where the
programmers were. Over time we were able to take the action closer to the
business stakeholders and describe the multilayered approach that is modern
BDD (and is also, ironically, classic TDD, which Kent Beck described from
the very outset as working on multiple levels of abstraction).
Aslak Hellesøy has been part of the effort to describe that shift almost from
the very beginning. As well as an early adopter of BDD—and a passionate
advocate of TDD—he rewrote my sad efforts at building a scenario runner for
RSpec into the tool we now call Cucumber. He has invested enormous time
and effort into both the tool and its community, so it came as no surprise to
learn he and Matt were writing a book on BDD in Cucumber. I love that they
1.
http://www.thefreedictionary.com/paradigm
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• Foreword
are targeting both developers and testers. If the tool isn’t bringing these two
worlds closer together, then it’s the wrong tool.
I was delighted to learn that Aslak’s partner in crime would be Matt Wynne.
Another passionate and experienced TDDer—and BDDer—Matt has been
involved with Cucumber since day one. He is a fun and engaging speaker, is
a great teacher, and has a wealth of knowledge and wit that comes across in
his writing. In fact, I’m proposing that Matt Wynne be inaugurated as a unit
of excellence, somewhere between a Win and an Epic Win. (Oh, cool, did you
see that? That was better than a win; that was a Matt Wynne!)
I hope you enjoy this book as much as I did. My review notes from an earlier
draft seem to contain the phrase “Oh, this is lovely” more times than I remembered. It feels like you are being led into a strange, yet somehow oddly familiar,
world with two knowledgeable and accommodating guides. Oodles of examples,
descriptions, and sidebars (Joe—who you’ll meet early on—quickly became
my friend by asking the things I found myself asking.) help you on your way,
and the authors manage to keep the plot moving quickly enough to keep you
engaged, which is always a challenge in a technical book.
I can’t say where BDD will be in another eight years, but with folks like Matt
and Aslak sharing their innovation and clarity, now is a very exciting time to
be involved in agile software development.
—Dan North, Lean technology specialist at DRW Trading and originator of BDD
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Acknowledgments
The first people we want to thank are the hundreds of you who contribute to
the Cucumber community. Whether you’re sharing ideas, experiences, and
opinions on the mailing list, helping people in the IRC channel, or contributing
new features and bug fixes to the codebase, it all helps. Without your contribution, there would be no Cucumber and therefore no book.
Writing this book has taken much more effort than either of us had anticipated. Throughout it all, our editor Jackie Carter has patiently been there at our
side, cajoling us when we needed it, chiding us when we deserved it, and
giving us thoughtful feedback at every opportunity. Jackie has made a massive
contribution to the quality of what you’re reading, and her name fully deserves
its place on the cover.
Thanks to our reviewers:
Lasse Koskela
George Dinwiddie
Rachel Davies
Ian Dees
Arti Mathanda
Robert Chatley
Kevin Rutherford Luis Lavena
Gojko Adzic
Crain Riecke
Sean Miller
Mike Sassak
Your suggestions and encouragement were greatly appreciated.
Thanks to all the beta readers who left us feedback, helping us iron out the
little mistakes we would never have seen ourselves.
Thanks to Dan North for his enthusiastic and generous foreword. Matt blames
Dan for introducing him to the idea of BDD, and it was his experiments with
JBehave and RBehave that caused Aslak to create Cucumber in the first
place. Dan has a lot to answer for.
From Matt: I want to thank the team at Songkick, especially Sabrina Leandro,
Niko Felger, Dan Lucraft, Phil Cowans, and Matt Johnson. Many of the lessons
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• Acknowledgments
in this book I learned with you. Greatest thanks go to my wonderful wife,
Anna, for believing in this project and giving me the support I needed to actually get it done. Imagine all the things we’ll be able to do now that it’s finished!
From Aslak: Dad, thanks for having the foresight to buy me a Commodore
64 in 1981. Patricia, my dear wife—thank you for the countless hours of
patience and encouragement. And for coming up with the silly but catchy
name Cucumber!
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Preface
Cucumber is a friendly tool. It wants to be part of your team, and it doesn’t
mind being the nitpicky nerd who can remember every single little detail about
what your system can and can’t do. Every team needs someone like that.
Even better than that, Cucumber will volunteer to do all the boring repetitive
checks that you need to run to make sure that the system is working as
expected. This frees your testers up to do interesting, creative work instead,
and it gives programmers the courage to perform major surgery to the code
when it’s required. Business stakeholders warm to Cucumber’s open attitude,
sharing everything that the development team is doing in terminology that
they can actually understand.
Cucumber is a young tool, but it’s already become clear that some people
misunderstand it. Those of us who were drawn to Cucumber from the beginning instinctively realized that it’s more than a testing tool; it’s a collaboration
tool. By writing this book, we hope to show you not just how to use Cucumber
but how to use it well.
Who This Book Is For
Cucumber is designed to help build bridges between the technical and nontechnical members of a software team, and we’ve tried to consider both of
those readers. The majority of the book is written to the technical reader,
someone who is interested in test automation and already has at least some
programming skill. However, several of the chapters—especially in the first
part of the book where we explain how to write the specifications themselves
—are written with the nontechnical reader very much in mind. Specifically,
those chapters are as follows:
• Chapter 1, Why Cucumber?, on page 3
• Chapter 3, Gherkin Basics, on page 25
• Chapter 5, Expressive Scenarios, on page 61
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• Preface
• Chapter 6, When Cucumbers Go Bad, on page 85
• Chapter 13, Adding Tests to a Legacy Application, on page 221
As the book develops, we’ll look at more complex testing situations, and the
level of technical know-how required to read the chapters will increase. We’ve
tried to make this buildup as gradual as possible so that if you’re only just
beginning your journey into test automation, you should be able to follow
along and learn as we go.
You Don’t Need to Know Ruby, But It Helps
Ruby1 is an open source programming language that can be installed and
run on all major operating systems. The original—and still most popular—
version of Cucumber is written in Ruby, and this book is about that version.
That doesn’t mean the system you’re testing has to be written in Ruby. One
of Ruby’s many strengths is how good it is at talking to other languages and
platforms, and we’ll show you how to use Ruby tools to test web-based systems
that could be written in any language.
To follow along with the coding examples in the technical chapters, it will
help if you know a little Ruby. Ruby is an easy language to learn, and the
Ruby examples we’ll use are deliberately simple. To get the best out of this
book, we suggest that Ruby novices accompany it with a copy of Everyday
Scripting with Ruby [Mar07] or Programming Ruby: The Pragmatic Programmer’s
Guide [TFH08].
It’s OK if You’re Not Test-Driven
We’ve had our greatest success with Cucumber as part of an outside-in
approach, starting with a failing Cucumber test and using that to drive our
development work on the application code. As developers, this way of working
helps us stay honest and avoid the temptation to build in functionality that
nobody asked us for, just in case it might be needed one day in the future.
Cucumber is a tool that facilitates this way of working, but it doesn’t force it
on you. Some teams use Cucumber to automate tests for the work that developers have already done. This can often be a first step toward adopting an
outside-in approach, as Cucumber’s readable tests start to attract the attention of the team’s nontechnical stakeholders, drawing them into the process.
Even if you’re using Cucumber to write tests against existing code, you’ll still
get a great deal of benefit from Cucumber over alternatives like QTP and
1.
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Why You Should Listen to Us
• xix
Selenium IDE, and we think you’ll still get a lot out of this book. We’re not
here to preach to you about process, but we will share our insights about
what has worked for us and why.
Why You Should Listen to Us
We’ve both been building software for a living for almost twenty years, and
using automated tests for nearly ten of those. Aslak created Cucumber in
2008, and Matt has been one of its most active users from day one.
We’ve used Cucumber to test all kinds of systems: from Ruby on Rails web
applications, through Flash games, to enterprise Java web services. We’ve
also trained hundreds of developers in how to use Cucumber, teaching the
material in this book at events and companies around the world.
The Cucumber community is full of lively debate, and we’ve spent many hours
of our spare time having our ideas challenged and honed in discussions with
other users. We hope we’ve distilled as much of that knowledge and experience
as possible in this book.
How This Book Is Organized
The book is in three parts. In Part I, we’ll take you through the core concepts
you need to know in order to make use of Cucumber. Novice readers will learn
everything they need to know to get up and running, and readers who are
already experienced with Cucumber should pick up plenty of useful detail
too.
Part II works through a practical example of developing a new application
using Cucumber. You’ll pair with us as we build a simple application from
scratch, giving you a chance to experience how we like to build software using
Cucumber and to consolidate what you’ve learned in Part I. We’ll also teach
you some advanced features of Cucumber that are easier to learn in the
context of an example.
Cucumber provides the framework for specifying and executing tests, but
there are a wide variety of systems that you might want to test. In Part III,
we’ve provided you with a broad selection of guides to using Cucumber in
some common situations, such as testing REST APIs, Ajax web applications,
and command-line applications.
What Is Not in This Book
Although it is possible to test Flash and mobile applications using Cucumber,
the details are sadly beyond the scope of this edition. Similarly, the flavors
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• Preface
of Cucumber that run natively on the JVM, JavaScript and C#, allowing you
to write your Cucumber code in the same language as your production code,
will not be covered. Cucumber’s wire protocol (a protocol for driving remote
systems over a TCP socket) is also out of scope.
We have provided a list of pointers to further information on this subject in
Appendix 1, Using Cucumber with Other Platforms, on page 295. For further
information about using Ruby to automate and test different kinds of system,
we recommend getting a copy of Scripted GUI Testing with Ruby [Dee08] by
Ian Dees to compliment our book.
Running the Code Examples
This book is full of practical examples, and we encourage you to follow along
with them to get the most out of the book. You’ll learn the most if you type
them in by hand as you read along, but if you’d prefer, you can always
download the code examples from http://pragprog.com/titles/hwcuc/
source_code.
To run the examples, you’ll need to install the Ruby language itself as well
as some additional libraries, which in Ruby are called gems. You can find the
full instructions in Appendix 2, Installing Cucumber, on page 299.
Windows Users
Most of the code examples work just the same on Windows and *nix operating
systems. On the rare occasions that they differ, you’ll find the Windows version
in a sidebar nearby, with a note in the body of the text pointing you to the
sidebar.
You’ll soon notice that we’ve used the $ symbol for the command prompt.
This is familiar to Linux or Mac users but might feel a little unfamiliar to
Windows users. So, when you’re looking at something like this:
$ cucumber
try to imagine you’re seeing this instead:
C:\> cucumber
Other than that, everything should work just the same for everyone.
Getting Help
If you’re stuck on one of the exercises in this book, there is a discussion forum
where you can ask for help at http://forums.pragprog.com/forums/166.
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Getting Help
• xxi
If you have a general question about Cucumber, the Cucumber community
will welcome you to their mailing list at https://groups.google.com/forum/
#!forum/cukes. Cucumber is an open source tool, which means that everyone
contributing to the group is volunteering their time, so please make sure
you’ve researched your question as thoroughly as you can before you ask for
help on the mailing list. People will be much more likely to help you if they
can see you’re trying to help yourself.
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Part I
Cucumber Fundamentals
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CHAPTER 1
Why Cucumber?
Software starts as an idea.
Let’s assume it’s a good idea—an idea that could make the world a better
place, or at least make someone some money. The challenge of the software
developer is to take the idea and make it real, into something that actually
delivers that benefit.
The original idea is perfect, beautiful. If the person who has the idea happens
to be a talented software developer, then we might be in luck: the idea could
be turned into working software without ever needing to be explained to
anyone else. More often, though, the person with the original idea doesn’t
have the necessary programming skill to make it real. Now the idea has to
travel from that person’s mind into other people’s. It needs to be communicated.
Most software projects involve teams of several people working collaboratively
together, so high-quality communication is critical to their success. As you
probably know, good communication isn’t just about eloquently describing
your ideas to others; you also need to solicit feedback to ensure you’ve been
understood correctly. This is why agile software teams have learned to work
in small increments, using the software that’s built incrementally as the
feedback that says to the stakeholders “Is this what you mean?”
Even this is not enough. If the developers spend a two-week iteration implementing a misunderstanding, not only have they wasted two weeks of effort,
but they’ve corrupted the integrity of the codebase with concepts and functionality that do not reflect the original idea. Other developers may have
already innocently started to build more code on top of those bad ideas,
making it unlikely they’ll ever completely disappear from the codebase.
We need a kind of filter to protect our codebase from these misunderstood
ideas.
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4
1.1
• Chapter 1. Why Cucumber?
Automated Acceptance Tests
The idea of automated acceptance tests originates in eXtreme Programming1
(XP), specifically in the practice of Test-Driven Development2 (TDD).
Instead of a business stakeholder passing requirements to the development
team without much opportunity for feedback, the developer and stakeholder
collaborate to write automated tests that express the outcome that the
stakeholder wants. We call them acceptance tests because they express what
the software needs to do in order for the stakeholder to find it acceptable. The
test fails at the time of writing, because no code has been written yet, but it
captures what the stakeholder cares about and gives everyone a clear signal
as to what it will take to be done.
These tests are different from unit tests, which are aimed at developers and
help them to drive out and check their software designs. It’s sometimes said
that unit tests ensure you build the thing right, while acceptance tests ensure
you build the right thing.
Automated acceptance testing has been an established practice among good
XP teams for years, but many less experienced agile teams seem to see TDD
as being a programmer activity only. As Lisa Crispin and Janet Gregory point
out in Agile Testing: A Practical Guide for Testers and Agile Teams [CG08],
without the business-facing automated acceptance tests, it’s hard for the
programmers to know which unit tests they need to write. Automated acceptance tests help your team to focus, ensuring the work you do each iteration
is the most valuable thing you could possibly be doing. You’ll still make mistakes—but you’ll make a lot less of them—meaning you can go home on time
and enjoy the rest of your life.
1.2
Behaviour-Driven Development
Behaviour-Driven Development3 (BDD) builds upon Test-Driven Development
(TDD) by formalizing the good habits of the best TDD practitioners. The best
TDD practitioners work from the outside-in, starting with a failing customer
acceptance test that describes the behavior of the system from the customer’s
point of view. As BDD practitioners, we take care to write the acceptance tests
as examples that anyone on the team can read. We make use of the process
of writing those examples to get feedback from the business stakeholders
about whether we’re setting out to build the right thing before we get started.
1.
2.
3.
Extreme Programming Explained: Embrace Change [Bec00]
Test Driven Development: By Example [Bec02]
http://behaviour-driven.org/
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Behaviour-Driven Development
•5
As we do so, we make a deliberate effort to develop a shared, ubiquitous language for talking about the system.
Ubiquitous language
As Eric Evans describes in his book Domain Driven Design [Eva03], many
software projects suffer from low-quality communication between the domain
experts and programmers on the team:
“A project faces serious problems when its language is fractured. Domain experts
use their jargon while technical team members have their own language tuned
for discussing the domain in terms of design... Across this linguistic divide, the
domain experts vaguely describe what they want. Developers, struggling to understand a domain new to them, vaguely understand.”
With a conscious effort by the team, a ubiquitous language can emerge that
is used and understood by everyone involved in the project. When the team
uses this language consistently in their conversations, documentation, and
code, the friction of translating between everyone’s different little dialects is
gone, and the chances of misunderstandings are greatly reduced.
Cucumber helps facilitate the discovery and use of a ubiquitous language
within the team, by giving the two sides of the linguistic divide a place where
they can meet. Cucumber tests interact directly with the developers’ code,
but they’re written in a medium and language that business stakeholders
can understand. By working together to write these tests—specifying collaboratively—not only do the team members decide what behavior they need to
implement next, but they learn how to describe that behavior in a common
language that everyone understands.
When we write these tests before development starts, we can explore and
eradicate many misunderstandings long before they ooze their way into the
codebase.
Examples
What makes Cucumber stand out from the crowd of other testing tools is that
it has been designed specifically to ensure the acceptance tests can easily be
read—and written—by anyone on the team. This reveals the true value of
acceptance tests: as a communication and collaboration tool. The easy readability of Cucumber tests draws business stakeholders into the process,
helping you really explore and understand their requirements.
Here’s an example of a Cucumber acceptance test:
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6
• Chapter 1. Why Cucumber?
Feature: Sign up
Sign up should be quick and friendly.
Scenario: Successful sign up
New users should get a confirmation email and be greeted
personally by the site once signed in.
Given I have chosen to sign up
When I sign up with valid details
Then I should receive a confirmation email
And I should see a personalized greeting message
Scenario: Duplicate email
Where someone tries to create an account for an email address
that already exists.
Given I have chosen to sign up
But I enter an email address that has already registered
Then I should be told that the email is already registered
And I should be offered the option to recover my password
Notice how the test is specified as examples of the way we want the system
to behave in particular scenarios. Using examples like this has an unexpectedly powerful effect in enabling people to visualize the system before it has
been built. Anyone on the team can read a test like this and tell you whether
it reflects their understanding of what the system should do, and it may well
spark their imagination into thinking of other scenarios that you’ll need to
consider too. Gojko Adzic’s book Specification by Example [Adz11] contains
many case studies of teams who have discovered this and used it to their
advantage.
Acceptance tests written in this style become more than just tests; they are
executable specifications.
1.3
Living Documentation
Cucumber tests share the benefit of traditional specification documents in
that they can be written and read by business stakeholders, but they have a
distinct advantage in that you can give them to a computer at any time to tell
you how accurate they are. In practice, this means that your documentation,
rather than being something that’s written once and then gradually goes out
of date, becomes a living thing that reflects the true state of the project.
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How Cucumber Works
•7
Source of Truth
For many teams, they become the definitive source of truth as to what the
system does. Having a single place to go for this information saves a lot of
time that is often wasted trying to keep requirements documents, tests, and
code all in sync. It also helps to build trust within the team, because different
parts of the team no longer have their own personal versions of the truth.
1.4
How Cucumber Works
Before we dive into the meat of the book, let’s give you some context with a
high-level overview of a typical Cucumber test suite.
Cucumber is a command-line tool. When you run it, it reads in your specifications from plain-language text files called features, examines them for
scenarios to test, and runs the scenarios against your system. Each scenario
is a list of steps for Cucumber to work through. So that Cucumber can understand these feature files, they must follow some basic syntax rules. The name
for this set of rules is Gherkin.
Along with the features, you give Cucumber a set of step definitions, which
map the business-readable language of each step into Ruby code to carry out
whatever action is being described by the step. In a mature test suite, the
step definition itself will probably just be one or two lines of Ruby that delegate
to a library of support code, specific to the domain of your application, that
knows how to carry out common tasks on the system. Normally that will
involve using an automation library, like the browser automation library
Capybara, to interact with the system itself.
This hierarchy, from features down to automation library, is illustrated by
Figure 1, Cucumber testing stack, on page 8.
If the Ruby code in the step definition executes without error, Cucumber
proceeds to the next step in the scenario. If it gets to the end of the scenario
without any of the steps raising an error, it marks the scenario as having
passed. If any of the steps in the scenario fail, however, Cucumber marks the
scenario as having failed and moves on to the next one. As the scenarios run,
Cucumber prints out the results showing you exactly what is working and
what isn’t.
That’s it in a nutshell. There are many other advantages to Cucumber that
make it an excellent choice: you can write your specifications in more than
forty different spoken languages, you can use tags to organize and group your
scenarios, and you can easily integrate with a host of high-quality Ruby
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• Chapter 1. Why Cucumber?
Your Project
Features
Business
Facing
Scenarios
Steps
Step Definitions
Technology
Facing
Support Code
Automation Library
Your System
Figure 1—Cucumber testing stack
automation libraries to drive almost any kind of application. All that and more
will become clear as you read the rest of the book.
1.5
What We Just Learned
Let’s review what we’ve covered so far.
Software teams work best when the developers and business stakeholders
are communicating clearly with one another. A great way to do that is to
collaboratively specify the work that’s about to be done using automated
acceptance tests.
When the acceptance tests are written as examples, they stimulate people’s
imaginations and help them see other scenarios they hadn’t previously
considered.
When the team write their acceptance tests collaboratively, they can develop
their own ubiquitous language for talking about their problem domain. This
helps them avoid misunderstandings.
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What We Just Learned
•9
Cucumber was designed specifically to help business stakeholders get involved
in writing acceptance tests.
Each test case in Cucumber is called a scenario, and scenarios are grouped
into features. Each scenario contains several steps.
The business-facing parts of a Cucumber test suite, stored in feature files,
must be written according to syntax rules—known as Gherkin—so that
Cucumber can read them.
Under the hood, step definitions translate from the business-facing language
of steps into Ruby code.
To illustrate these concepts, in the next chapter we’re going to dive right in
and build a very simple application, using Cucumber to drive the development.
Try This
Cucumber has its own ubiquitous language. Can you list the terms about
Cucumber’s domain you’ve learned in this chapter and describe what you
think each of them means?
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CHAPTER 2
First Taste
We figured you’d be eager to start playing with your shiny new toy right away,
so we’re going to work through a simple example that will give you a feel for
what it’s like to work with Cucumber. You might not quite understand everything that happens here just yet, but try not to let that worry you. We’ll come
back and fill in the details over the next few chapters.
We’re going to build a simple command-line application from the outside-in,
driving our development with Cucumber. Watch how we proceed in very small
baby steps, going back to run Cucumber after we make each change. This
patient rhythm is an important characteristic of working effectively with
Cucumber, but it’s much easier to demonstrate than to explain.
Assuming you want to follow along with the action in this chapter (it’ll be a
lot more fun if you do), you’ll need to have Cucumber installed. If you haven’t
already done so, see Appendix 2, Installing Cucumber, on page 299 for installation instructions.
Right...shall we get started then?
2.1
Understanding Our Goal
Our goal is to write a program that can perform calculations. Some people
might call it a calculator.
We have an incredible vision of what this calculator will one day become: a
cloud-based service that runs on mobile phones, desktops, and browsers,
uniting the world with the opportunity of ubiquitous mathematical operations.
We’re pragmatic businesspeople, though, so the first release of our program
has to be as simple as possible. The first release will be a command-line
program, implemented as a Ruby script. It will take input containing the
calculation to be done and display the result at the command prompt.
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• Chapter 2. First Taste
So, for example, if the input file looks like this:
2+2
then the output would be 4.
Similarly, if the input file looks like this:
100/2
then the output would be 50.
You get the idea.
2.2
Creating a Feature
Cucumber tests are grouped into features. We use this name because we
want them to describe the features that a user will be able to enjoy when
using our program. The first thing we need to do is make a directory where
we’ll store our new program along with the features we’ll be writing for it.
$ mkdir calculator
$ cd calculator
We’re going to let Cucumber guide us through the development of our calculator program, so let’s start right away by running cucumber in this empty
folder:
$ cucumber
You don't have a 'features' directory. Please create one to get started.
See http://cukes.info/ for more information.
Since we didn’t specify any command-line arguments, Cucumber has assumed
that we’re using the conventional features folder to store our tests. That would
be fine, except that we don’t have one yet. Let’s follow the convention and
create a features directory:
$ mkdir features
Now run Cucumber again.
$ cucumber
0 scenarios
0 steps
0m0.000s
Each Cucumber test is called a scenario, and each scenario contains steps
that tell Cucumber what to do. This output means that Cucumber is happily
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Creating a Feature
• 13
scanning the features directory now, but it didn’t find any scenarios to run.
Let’s create one.
Our user research has shown us 67 percent of all mathematical operations
are additions, so that’s the operation we want to support first. In your favorite
editor, create a plain-text file called features/adding.feature:
Download first_taste/01/features/adding.feature
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
When the calculator is run
Then the output should be "4"
This .feature file contains the first scenario for our calculator program. We’ve
translated one of the examples we were given in the previous section into a
Cucumber scenario that we can ask the computer to run over and over again.
You can probably see that Cucumber expects a little bit of structure in this
file. The keywords Feature, Scenario, Given, When, and Then are the structure, and
everything else is documentation. Although some of the keywords are
highlighted here in the book—and they may be in your editor too—it’s just a
plain-text file. The structure is called Gherkin.
When you save this file and run cucumber, you should see a great deal more
output than the last time:
$ cucumber
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
When the calculator is run
Then the output should be "4"
1 scenario (1 undefined)
3 steps (3 undefined)
0m0.003s
You can implement step definitions for undefined steps with these snippets:
Given /^the input "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
When /^the calculator is run$/ do
pending # express the regexp above with the code you wish you had
end
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Then /^the output should be "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
If you want snippets in a different programming language,
just make sure a file with the appropriate file extension
exists where cucumber looks for step definitions.
Wow, that’s a lot of output all of a sudden! Let’s take a look at what’s going
on here. First, we can see that Cucumber has found our feature and is trying
to run it. We can tell this because Cucumber has repeated the content of the
feature back to us. You might also have noticed that the summary output 0
scenarios has changed to 1 scenario (undefined). This means that Cucumber has
read the scenario in our feature but doesn’t know how to run it yet.
Second, Cucumber has printed out three code snippets. These are sample
code for step definitions, written in Ruby, which tell Cucumber how to translate
the plain English steps in the feature into actions against our application.
Our next step will be to put these snippets into a Ruby file where we can start
to flesh them out.
Before we explore beneath the layer of business-facing Gherkin features into
step definitions, it’s worth taking a quick look at the map in case anyone is
feeling lost. Figure 2, The main layers of a Cucumber test suite, on page 15
reminds us how things fit together. We start with features, which contain our
scenarios and steps. The steps of our scenarios call step definitions that
provide the link between the Gherkin features and the application being built.
Now we’ll implement some step definitions so that our scenario is no longer
undefined.
2.3
Creating Step Definitions
Without thinking too much about what they mean, let’s just copy and paste
the snippets from Cucumber’s last output into a Ruby file. Just like the features, Cucumber is expecting the step definitions to be found in a conventional
place:
$ mkdir features/step_definitions
Now create a Ruby file in features/step_definitions, called calculator_steps.rb. Cucumber
won’t mind what you call it as long as it’s a Ruby file, but this is a good name
to use. Open it in your text editor and paste in those snippets:
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Creating Step Definitions
• 15
Features
(Gherkin)
(Ruby)
Your App
Figure 2—The main layers of a Cucumber test suite
Download first_taste/02/features/step_definitions/calculator_steps.rb
Given /^the input "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
When /^the calculator is run$/ do
pending # express the regexp above with the code you wish you had
end
Then /^the output should be "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
Running cucumber will tell us what to do next:
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
TODO (Cucumber::Pending)
./features/step_definitions/calculator_steps.rb:2
features/adding.feature:4
When the calculator is run
Then the output should be "4"
1 scenario (1 pending)
3 steps (2 skipped, 1 pending)
0m0.002s
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• Chapter 2. First Taste
The scenario has graduated from undefined to pending. This is good news, because
it means Cucumber is now running the first step, but as it did so, it hit the
call to pending inside our copied-and-pasted step definition code, which tells
Cucumber that this scenario is still a work in progress. We need to replace
that pending marker with a real implementation.
Notice that Cucumber reports the two other steps as skipped. As soon as it
encounters a failed or pending step, Cucumber will stop running the scenario
and skip the remaining steps.
Let’s implement the first step definition.
2.4
Implementing Our First Step Definition
We’ve decided this first release of our calculator is going to take its input from
the user as a command-line argument, so our job in the step definition for
Given the input "2+2" is just to remember the input so that we know what to pass
on the command line when we run the calculator in the next step. In the
features/step_definitions folder, edit the calculator_steps.rb file so that the first step
definition looks like this:
Download first_taste/03/features/step_definitions/calculator_steps.rb
Given /^the input "([^"]*)"$/ do |input|
@input = input
end
All we’ve done here is store the input from the feature in a Ruby instance
variable. That instance variable will be around for as long as this particular
scenario is running, so we can use it again in the next step when we actually
run the calculator.
Great, that was easy. Now, where were we again? Let’s ask cucumber:
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
When the calculator is run
TODO (Cucumber::Pending)
./features/step_definitions/calculator_steps.rb:9
features/adding.feature:5
Then the output should be "4"
1 scenario (1 pending)
3 steps (1 skipped, 1 pending, 1 passed)
0m0.002s
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Running Our Program
• 17
Yay! Our first step passed! The scenario is still marked as pending, of course,
because we still have the other two steps to implement, but we’re starting to
get somewhere.
2.5
Running Our Program
To implement the next step, edit features/step_definitions/calculator_steps.rb so that
the second step definition looks like this:
Download first_taste/04/features/step_definitions/calculator_steps.rb
When /^the calculator is run$/ do
@output = `ruby calc.rb #{@input}`
raise('Command failed!') unless $?.success?
end
This code attempts to run our calculator program calc.rb, passing it the input
we stored in the first step and storing any output in another instance variable.
Then it checks a specially—but rather cryptically—named Ruby variable $?
to check whether the command succeeded and raises an error if it didn’t.
Remember that Cucumber fails a step if the step definition raises an error;
this is the simplest way to do it.
This time when we run Cucumber, we should see that it has actually tried
to run our calculator:
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
ruby: No such file or directory -- calc.rb (LoadError)
When the calculator is run
Command failed! (RuntimeError)
./features/step_definitions/calculator_steps.rb:10
features/adding.feature:5
Then the output should be "4"
Failing Scenarios:
cucumber features/adding.feature:3
1 scenario (1 failed)
3 steps (1 failed, 1 skipped, 1 passed)
0m0.027s
Our step is failing, because we don’t have a calc.rb program to run yet. You
should see that Cucumber has highlighted the output from our raised error
in red just beneath the step, helping you spot the problem.
You might well think it’s a bit odd that we’ve written and run code that tries
to run our calc.rb program, knowing perfectly well that the file doesn’t even
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• Chapter 2. First Taste
exist yet. We do this deliberately, because we want to make sure we have a
fully functioning test in place before we drop down to working on the solution.
Having the discipline to do this means we can trust our tests, because we’ve
seen them fail, and this gives us confidence that when the tests pass, we’re
really done. This gentle rhythm is a big part of what we call outside-in development, and while it might seem strange at first, we hope to show you
throughout the book that it has some great benefits.
Another benefit of working from the outside-in is that we’ve had a chance to
think about the command-line interface to our calculator from the point of
view of a user, without having made any effort to implement it yet. At this
stage, if we realize there’s something we don’t like about the interface, it’s
very easy for us to change it.
2.6
Changing Formatters
We think it’s starting to get distracting looking at the whole content of the
feature in Cucumber’s output each time we run. Let’s switch to the progress
formatter to get a more focused output. Run this command:
$ cucumber --format progress
You should see the following output:
.ruby: No such file or directory -- calc.rb (LoadError)
F(::) failed steps (::)
Command failed! (RuntimeError)
./features/step_definitions/calculator_steps.rb:10
features/adding.feature:5
Failing Scenarios:
cucumber features/adding.feature:3 # Scenario: Add two numbers
1 scenario (1 failed)
3 steps (1 failed, 1 skipped, 1 passed)
0m0.023s
Instead of printing the whole feature, the progress formatter has printed three
characters in the output, one for each step. The first . character means the
step passed. The F character means the second step, as we know, has failed.
The final - character means that the last step has been skipped. Cucumber
has several different formatters that you can use to produce different types
of output as your features run; you’ll learn more about them through the
course of the book.
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Adding an Assertion
• 19
Formatters
Cucumber formatters allow you to visualize the output from your test run in different
ways. There are formatters that produce HTML reports, formatters that produce JUnit
XML for continuous integration servers like Jenkins, and many more.
Use cucumber --help to see the different formatters that are available and try some out
for yourself. We’ll explain more about formatters in Chapter 11, The Cucumber Command-Line Interface, on page 191.
That was an interesting little diversion, but let’s get back to work. We have a
failing test to fix!
2.7
Adding an Assertion
So, following Cucumber’s lead, we need to create a Ruby file for our program.
Let’s just create an empty Ruby file for the time being so that we can stay on
the outside and get the test finished before we go on to the solution. Linux/
Mac users can type this to create an empty file:
$ touch calc.rb
If you’re using Windows, there is no touch command, so either just create an
empty text file named calc.rb in your editor or use this little trick:
C:\> echo.>calc.rb
When we run cucumber again, we should see that the second step is passing
and we’re on to the final step:
$ cucumber --format progress
..P
(::) pending steps (::)
features/adding.feature:6:in ‘Then the output should be "4"’
1 scenario (1 pending)
3 steps (1 pending, 2 passed)
0m0.460s
To get the last step definition working, change the last step definition in
features/step_definitions/calculator_steps.rb to look like this:
Download first_taste/07/features/step_definitions/calculator_steps.rb
Then /^the output should be "([^"]*)"$/ do |expected_output|
@output.should == expected_output
end
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• Chapter 2. First Taste
We’re using an RSpec1 assertion to check that the expected output specified
in the feature matches the output from our program that we stored in @output
in the previous step definition. If it doesn’t, RSpec will raise an error just like
we did using raise in the last step definition.
Now when we run cucumber, we have ourselves a genuine failing test:
$ cucumber --format progress
..F
(::) failed steps (::)
expected: "4"
got: "" (using ==) (RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/calculator_steps.rb:16
features/adding.feature:6
Failing Scenarios:
cucumber features/adding.feature:3 # Scenario: Add two numbers
1 scenario (1 failed)
3 steps (1 failed, 2 passed)
0m0.587s
Great! Now our test is failing for exactly the right reason: it’s running our
program, examining the output, and telling us just what the output should
look like. This is a natural point to pause for a break. We’ve done the hard
work for this release: when we come back to this code, Cucumber will be
telling us exactly what we need to do to our program to make it work. If only
all our requirements came ready-rolled with a failing test like this, building
software would be easy!
Try This
Can you write an implementation of calc.rb that makes the scenario pass?
Remember at this stage, we have only a single scenario to satisfy, so you
might be able to get away with quite a simple solution.
We’ll show you our solution in the next section.
2.8
Making It Pass
So, now that we have our solid failing Cucumber scenario in place, it’s time
to let that scenario drive out a solution.
1.
The RSpec Book [CADH09]
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Making It Pass
• 21
Joe asks:
I Feel Weird: You’re Making Tests Pass but Nothing
Works!
We’ve implemented a step that calls the calculator program and passes, even though
the “program” is just an empty file. What’s going on here?
Remember that a step isn’t a test in itself. The test is the whole scenario, and that
isn’t going to pass until all of its steps do. By the time we’ve implemented all of the
step definitions, there’s only going to be one way to make the whole scenario pass,
and that’s to build a calculator that can perform additions!
When we work outside-in like this, we often use temporary stubs like the empty calculator program as placeholders for details we need to fill in later. We know that we
can’t get away with leaving that as an empty file forever, because eventually Cucumber
is going to tell us to come back and make it do something useful in order to get the
whole scenario to pass.
This principle, deliberately doing the minimum useful work the tests will let us get
away with, might seem lazy, but in fact it’s a discipline. It ensures that we make our
tests thorough: if the test doesn’t drive us to write the right thing, then we need a
better test.
There is a very simple solution that will make the test pass, but it’s not going
to get us very far. Let’s try it anyway, for fun:
Download first_taste/08/calc.rb
print "4"
Try it. You should see the scenario pass at last:
...
1 scenario (1 passed)
3 steps (3 passed)
0m0.479s
Hooray! So, what’s wrong with this solution? After all, we already said that
we want to do the minimum work that the tests will let us get away with,
right?
Actually, that’s not quite what we said. We said we want to do the minimum
useful work that the tests will let us get away with. What we’ve done here
might have made the test pass, but it isn’t very useful. Apart from the fact
that it certainly isn’t going to function as a calculator yet, let’s look at what
we’ve missed out on testing with our smarty-pants one-liner solution:
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• Chapter 2. First Taste
• We haven’t tried to read the input from the command line.
• We haven’t tried to add anything up.
In Crystal Clear: A Human-Powered Methodology for Small Teams [Coc04],
Alistair Cockburn advocates building a walking skeleton as early as possible
in a project to try to flush out any potential problems with your technology
choices. Obviously, our calculator is trivially simple, but it’s still worth considering this principle: why don’t we build something more useful that passes
this scenario and helps us learn more about our planned implementation?
If you’re unconvinced by that argument, try looking at it as a problem of
duplication. We have a hard-coded value of 4 in two places: once in our scenario and once in our calculator program. In a more complex system, this
kind of duplication might go unnoticed, and we’d have a brittle scenario.
Let’s force ourselves to fix this, using what Kent Beck calls triangulation (Test
Driven Development: By Example [Bec02]). We’ll add another scenario to our
feature, using a new keyword called a Scenario Outline:
Download first_taste/09/features/adding.feature
Feature: Adding
Scenario Outline: Add two numbers
Given the input "<input>"
When the calculator is run
Then the output should be "<output>"
Examples:
| input | output |
| 2+2
| 4
|
| 98+1 | 99
|
We’ve turned our scenario into a Scenario Outline, which lets us specify multiple
scenarios using a table. We could have copied and pasted the whole scenario
and just changed the values, but we think this is a more readable way of
expressing the examples, and we want to give you a taste of what’s possible
with Gherkin’s syntax. Let’s see what the output looks like now:
$ cucumber
Feature: Adding
Scenario Outline: Add two numbers
Given the input "<input>"
When the calculator is run
Then the output should be "<output>"
Examples:
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What We Just Learned
• 23
| input | output |
| 2+2
| 4
|
| 98+1 | 99
|
expected: "99"
got: "4" (using ==) (RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/calculator_steps.rb:15
features/adding.feature:6
Failing Scenarios:
cucumber features/adding.feature:3
2 scenarios (1 failed, 1 passed)
6 steps (1 failed, 5 passed)
0m1.035s
We can see from the summary 2 scenarios (1 failed, 1 passed) that Cucumber has
run two scenarios. Each row in the Examples table is expanded into a scenario
when Cucumber runs the scenario outline. The first example—where the result
is 4—still passes, but the second example is failing.
Now it definitely makes sense to reimplement our program with a more realistic solution:
Download first_taste/10/calc.rb
print eval(ARGV[0])
First we read the command-line argument ARGV[0] and send it to Ruby’s eval
method. That should be able to work out what to do with the calculation input.
Finally, we print the result of eval to the console.
Try that. Do both scenarios pass? Great! You’ve just built your first program
with Cucumber.
2.9
What We Just Learned
We’ve taken a quick skim over a lot of different things in this chapter, all of
which will be covered again in more detail later. Let’s recap and highlight
some of the most important points.
Directory Structure
Cucumber likes you to use a conventional directory structure for storing your
features and step definitions:
features/
adding.feature
...
step_definitions/
calculator_steps.rb
...
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You can override this structure, if you really want to, by passing arguments
to Cucumber, but this is the conventional and simplest way to store your
files.
Baby Steps
As we progressed through the example, did you notice how often we ran
cucumber?
One of the things we love about working outside-in with Cucumber is how it
helps us to stay focused. We can let Cucumber guide us through the work to
be done, leaving us free to concentrate on creating an elegant solution. By
running Cucumber every time we make a change, any mistakes we make are
found and resolved quickly, and we get plenty of feedback and encouragement
about our progress.
Gherkin
Cucumber tests are expressed using a syntax called Gherkin. Gherkin files
are plain text and have a .feature extension. We’ll talk more about Gherkin in
Chapter 3, Gherkin Basics, on page 25.
Step Definitions
Step definitions are the Ruby glue that binds your Cucumber tests to the
application you’re testing. When the whole thing plays together, it looks a bit
like Figure 2, The main layers of a Cucumber test suite, on page 15.
You’ll learn more about step definitions in Chapter 4, Step Definitions: From
the Outside, on page 39.
After that whistle-stop tour of Cucumber’s features, we’re going to slow down
and get into a bit more depth. We’ll work our way in through the layers over
the next few chapters, starting with a look at Gherkin, the language we use
to write Cucumber features.
Try This
See whether you can add a second feature, division.feature, using the other
example from the start of this chapter. Do you need to change the solution
to make it pass?
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CHAPTER 3
Gherkin Basics
Now that you’ve gained some confidence with how Cucumber works, it’s worth
stepping back for a few moments and doing a little studying. We’re going to
look at Gherkin, the language we use for writing Cucumber features.
By the end of this chapter you’ll understand how to write specifications for
your software that can be both read by your stakeholders and tested by
Cucumber. You’ll learn what each of the Gherkin keywords does and how
they all fit together to make readable, executable Cucumber specifications.
You won’t know how to run the tests yet, but you’ll be ready to write them.
3.1
What’s Gherkin For?
When we build software for people (let’s call them stakeholders), it’s notoriously difficult to figure out exactly what they want us to build. In his famous
essay, No Silver Bullet [Bro95], Fred Brooks says:
“The hardest single part of building a software system is deciding precisely
what to build.”
We’ve all worked on projects where, because of a misunderstanding, code
that we’d worked hard on for several days or more had to be thrown away.
Better communication between developers and stakeholders is essential to
help avoid this kind of wasted time. One technique that really helps facilitate
this communication is the use of concrete examples to illustrate what we want
the software to do.
Concrete Examples
By using real-world examples to describe the desired behavior of the system
we want to build, we stay grounded in language and terminology that makes
sense to our stakeholders: we’re speaking their language. When we talk in
terms of these examples, they can really imagine themselves using the system,
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• Chapter 3. Gherkin Basics
and that means they can start to give us useful feedback and ideas before a
line of code has been written.
To illustrate this, let’s imagine you’re building a credit card payment system.
One of the requirements is to make sure users can’t enter bad data. Here’s
one way of expressing that:
Customers should be prevented from entering invalid credit card details.
This is an example of what agile teams often call acceptance criteria or conditions of satisfaction.1 We use the word acceptance because they tell us what
the system must be able to do in order for our stakeholders to find it acceptable.
The previous requirements statement is useful, but it leaves far too much
room for ambiguity and misunderstanding. It lacks precision. What exactly
makes a set of details invalid? How exactly should the user be prevented from
entering them? We’ve seen too many projects get dragged into the tar pit2 by
these kind of worthy but vague statements. Let’s try illustrating this requirement with a concrete example:
If a customer enters a credit card number that isn’t exactly 16 digits long, when
they try to submit the form, it should be redisplayed with an error message advising
them of the correct number of digits.
Can you see how much more specific this second statement is? As a developer
implementing this feature, we know almost everything we need to be able to
sit down and start working on the code. As a stakeholder, we have a much
clearer idea of what the developer is going to build.
In fact, a stakeholder reading this might point out that there are certain types
of cards that are valid with less than 16 digits and give us another example.
This is the real power of examples: they stimulate our imagination, enabling
us to explore and discover edge cases we might otherwise have found much
later.
By giving an example to illustrate our requirement, we’ve turned an acceptance
criterion into an acceptance test. Now we have something unambiguous that
we can use to test the behavior of the system, either manually or using an
automated test script.
1.
2.
Agile Estimating and Planning [Coh05]
The tar pit metaphor comes from the seminal book by Fred Brooks, The Mythical Man
Month: Essays on Software Engineering [Bro95].
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What’s Gherkin For?
• 27
Try This
Think about a feature you’re working on right now or have worked on recently.
Can you write down three concrete examples of the behavior needed for that
feature to be acceptable?
Executable Specifications
Another advantage of using concrete examples is that they’re much easier to
validate against the running system than vague requirement statements. In
fact, if we’re neat and tidy about how we express them, we can get the computer to check them for us. We call this automated acceptance testing.3
The challenge with writing good automated acceptance tests is that, for them
to be really effective, they need to be readable by not only the computer but
also by our stakeholders. It’s this human readability that allows us to get
feedback about what we’re building while we’re building it. This is where
Gherkin comes in.
Gherkin gives us a lightweight structure for documenting examples of the
behavior our stakeholders want, in a way that it can be easily understood
both by the stakeholders and by Cucumber. Although we can call Gherkin a
programming language,4 its primary design goal is human readability,
meaning you can write automated tests that read like documentation. Here’s
an example:
Download gherkin_basics/sample.feature
Feature: Feedback when entering invalid credit card details
In user testing we've seen a lot of people who made mistakes
entering their credit card. We need to be as helpful as possible
here to avoid losing users at this crucial stage of the
transaction.
Background:
Given I have chosen some items to buy
And I am about to enter my credit card details
Scenario: Credit card number too short
When I enter a card number that's only 15 digits long
And all the other details are correct
And I submit the form
Then the form should be redisplayed
And I should see a message advising me of the correct number of digits
3.
4.
Extreme Programming Explained: Embrace Change [Bec00]
A note for the pedantic reader: the Gherkin language does have a grammar enforced
by a parser, but the language is not Turing Complete.
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Scenario: Expiry date invalid
When I enter a card expiry date that's in the past
And all the other details are correct
And I submit the form
Then the form should be redisplayed
And I should see a message telling me the expiry date must be wrong
One interesting feature of Gherkin’s syntax is that it is not tied down to one
particular spoken language. Each of Gherkin’s keywords has been translated
into more than forty different spoken languages, and it is perfectly valid to
use any of them to write your Gherkin features. No matter if your users speak
Norwegian or Spanish, med Gherkin kan du beskrive funksjonalitet i et språk
de vil forstå.5 Tocino grueso!6 More on that later.
3.2
Format and Syntax
Gherkin files use the .feature file extension. They’re saved as plain text,
meaning they can be read and edited with simple tools. In this respect,
Gherkin is very similar to file formats like Markdown, Textile, and YAML.
Keywords
A Gherkin file is given its structure and meaning using a set of special keywords. There’s an equivalent set of these keywords in each of the supported
spoken languages, but for now let’s take a look at the English ones:
•
•
•
•
•
•
•
•
•
•
•
Feature
Background
Scenario
Given
When
Then
And
But
*
Scenario Outline
Examples
We’ll spend the rest of this chapter exploring how to use the most common
of these keywords, which will be enough to get you started writing your own
5.
6.
Gherkin lets you to write your features in a language they will understand.
Chunky Bacon!
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Feature
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Cucumber features. We’ll come back to look at the remaining keywords later
in Chapter 5, Expressive Scenarios, on page 61.
Dry Run
All of the examples in this chapter are valid Gherkin and can be parsed by
Cucumber. If you want to play around with them as we go through the
chapter, just create a test.feature working file. Then run it with the following:
$ cucumber test.feature --dry-run
The --dry-run switch tells Cucumber to parse the file without executing it. It
will tell you if your Gherkin isn’t valid.
3.3
Feature
Each Gherkin file begins with the Feature keyword. This keyword doesn’t really
affect the behavior of your Cucumber tests at all; it just gives you a convenient
place to put some summary documentation about the group of tests that
follow.
Here’s an example:
Feature: This is the feature title
This is the description of the feature, which can
span multiple lines.
You can even include empty lines, like this one:
In fact, everything until the next Gherkin keyword is included
in the description.
The text immediately following on the same line as the Feature keyword is the
name of the feature, and the remaining lines are its description. You can
include any text you like in the description except a line beginning with one
of the words Scenario, Background, or Scenario Outline. The description can span
multiple lines. It’s a great place to wax lyrical with details about who will use
the feature, and why, or to put links to supporting documentation such as
wireframes or user research surveys.
It’s conventional to name the feature file by converting the feature’s name to
lowercase characters and replacing the spaces with underscores. So, for
example, the feature named User logs in would be stored in user_logs_in.feature.
In valid Gherkin, a Feature must be followed by one of the following:
• Scenario
• Background
• Scenario Outline
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Although Background and Scenario Outline are handy keywords to know once you’ve
written a few scenarios, we don’t need to worry about them just yet. They’re
covered later in Chapter 5, Expressive Scenarios, on page 61. Right now all
we need is the Scenario.
3.4
Scenario
To actually express the behavior we want, each feature contains several scenarios. Each scenario is a single concrete example of how the system should
behave in a particular situation. If you add together the behavior defined by
all of the scenarios, that’s the expected behavior of the feature itself.
When Cucumber runs a scenario, if the system behaves as described in the
scenario, then the scenario will pass; if not, it will fail. Each time you add a
new scenario to your Cucumber test suite and make it pass, you’ve added
some new functionality to the system, and that’s time for a high-five.
Each feature typically has somewhere between five and twenty scenarios,
each describing different examples of how that feature should behave in different circumstances. We use scenarios to explore edge cases and different
paths through a feature.
Scenarios all follow the same pattern:
1. Get the system into a particular state.
2. Poke it (or tickle it, or ...).
3. Examine the new state.
So, we start with a context, go on to describe an action, and then finally check
that the outcome was what we expected. Each scenario tells a little story
describing something that the system should be able to do.
Given, When, Then
In Gherkin, we use the keywords Given, When, and Then to identify those three
different parts of the scenario:
Scenario: Successful withdrawal from an
Given I have $100 in my account # the
When I request $20
# the
Then $20 should be dispensed
# the
account in credit
context
event(s)
outcome(s)
So, we use Given to set up the context where the scenario happens, When to
interact with the system somehow, and Then to check that the outcome of that
interaction was what we expected.
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Scenario
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A Template for Describing a Feature
Although feature descriptions are often helpful documentation, they’re not mandatory.
If you’re struggling to work out what to say, the following template can be a great
place to start:
In order to <meet some goal>
As a <type of stakeholder>
I want <a feature>
By starting with the goal or value that the feature provides, you’re making it explicit
to everyone who ever works on this feature why they’re giving up their precious time.
You’re also offering people an opportunity to think about other ways that the goal
could be met. Maybe you don’t actually need to build this feature at all, or you could
deliver the same value in a much simpler way.
This template is known as a Feature Injection template, and we are grateful to Chris
Matts and Liz Keogh for sharing it with us.
And, But
Each of the lines in a scenario is known as a step. We can add more steps to
each Given, When, or Then section of the scenario using the keywords And and
But:
Scenario: Attempt withdrawal using stolen card
Given I have $100 in my account
But my card is invalid
When I request $50
Then my card should not be returned
And I should be told to contact the bank
Cucumber doesn’t actually care which of these keywords you use; the choice
is simply there to help you create the most readable scenario. If you don’t
want to use And or But, you could write the previous scenario like this, and it
would still work exactly the same way:
Scenario: Attempt withdrawal using stolen card
Given I have $100 in my account
Given my card is invalid
When I request $50
Then my card should not be returned
Then I should be told to contact the bank
But that doesn’t read as nicely, does it?
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Replacing Given/When/Then with Bullets
Some people find Given, When, Then, And, and But a little verbose. There is an
additional keyword you can use to start a step: * (an asterisk). We could have
written the previous scenario like this:
Scenario: Attempt withdrawal using stolen card
* I have $100 in my account
* my card is invalid
* I request $50
* my card should not be returned
* I should be told to contact the bank
To Cucumber, this is exactly the same scenario. Do you find this version
easier to read? Maybe. Did some of the meaning get lost? Maybe. It’s up to
you and your team how you want to word things. The only thing that matters
is that everybody understands what’s communicated.
Stateless
When writing scenarios, here’s a really important concept you need to grasp:
Each scenario must make sense and be able to be executed independently of
any other scenario.
That means you can’t put some money into the account in one scenario and
then expect that money to be there in the next scenario. Cucumber won’t
stop you from doing this, but it’s extremely bad practice: you’ll end up with
scenarios that fail unexpectedly and are harder to understand.
This might seem a little dogmatic, but trust us, it really helps keep your scenarios simple to work with. It avoids building up brittle dependencies between
scenarios and also gives you the flexibility to run just the scenarios you need
to when you’re working on a particular part of the system, without having to
worry about getting the right test data set up. We explain these problems in
depth in Chapter 6, When Cucumbers Go Bad, on page 85.
When writing a scenario, always assume that it will run against the system
in a default, blank state. Tell the story from the beginning, using Given steps
to set up all the state you need for that particular scenario.
Name and Description
Just like a Feature, a Scenario keyword can be followed by a name and description. Normally you’ll probably just use the name, but it’s valid Gherkin to
follow the name with a multiline description—everything up until the first
Given, When, or Then will be slurped up into the description of the scenario.
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Comments
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Stale scenario names can cause confusion. When modifying existing scenarios
(or copying and pasting them), take care to check that the name still makes
sense. Since the scenario name is just documentation, Cucumber won’t fail
the scenario even if its name no longer has anything to do with what’s actually going on in the steps. This can be really confusing for anyone reading
the scenario later.
Try This
• Now that you understand how to write Gherkin scenarios, try converting
some of the concrete examples you wrote down earlier for your own project
into Gherkin.
• Show them to someone who knows nothing about your project, and ask
them what they think your application does.
• Practice describing what you’re doing with Given/When/Then while you’re
doing everyday things such as starting your car, cooking breakfast, or
switching channels on the TV. You’ll be surprised how well it fits.
3.5
Comments
As well as the description fields that follow Feature and Scenario keywords,
Cucumber allows you to precede these keywords with comments.
Like in Ruby, comments start with a # character. Unlike in Ruby, comments
have to be the first and only thing on a line (well, apart from whitespace).
Here’s an example:
Download gherkin_basics/comments_example.feature
# This feature covers the account transaction and hardware-driver modules
Feature: Withdraw Cash
In order to buy beer
As an account holder
I want to withdraw cash from the ATM
# Can't figure out how to integrate with magic wand interface
Scenario: Withdraw too much from an account in credit
Given I have $50 in my account
# When I wave my magic wand
And I withdraw $100
Then I should receive $100
You can also put comments within a scenario. The most common use for this
is to comment out a step, as we’ve shown in the previous example.
As in any programming language, comments can quickly go stale and become
meaningless or downright confusing. When this happens, the comment
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• Chapter 3. Gherkin Basics
Matt says:
Take Care with Your Naming Scenarios
Even though they can’t make your tests pass or fail, scenario names are surprisingly
important to get right. Here are some reasons why it’s a good idea to pay attention
to them:
• When your tests break, it’s the failing scenario’s name that will give you the
headline news on what’s broken. A concise, expressive name here can save
everyone a lot of time.
• Once you have a few scenarios in a feature file, you don’t want to have to read
the detail of the steps unless you really need to do so. If you’re a programmer,
think of it a bit like method naming. If you name the method well, you won’t
need to read the code inside it to work out what it does.
• As your system evolves, your stakeholders will quite often ask you to change the
expected behavior in an existing scenario. A well-composed scenario name will
still make sense even if you add an extra Then step or two.
A good tip is to avoid putting anything about the outcome (the Then part) of the scenario
into the name and concentrate on summarizing the context and event (Given and When)
of the scenario.
causes more harm than good. We advise you to use them as sparingly as you
can and put the important stuff into scenarios where it can be tested.
3.6
Spoken languages
Remember earlier we said that you can write your Gherkin features in the
spoken language of your stakeholders? Here’s how.
Putting a # language: comment on the first line of a feature file tells Cucumber
which spoken language that feature is written in. If you omit this header,
Cucumber will default to English, as you’ve already seen.
Here’s an example of a feature written in Norwegian:
# language: no
Egenskap: Summering
For å unngå at firmaet går konkurs
Må regnskapsførerere bruke en regnemaskin for å legge sammen tall
Scenario: to tall
Gitt at jeg har tastet inn 5
Og at jeg har tastet inn 7
Når jeg summerer
Så skal resultatet være 12
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What We Just Learned
• 35
Joe asks:
Why Do We Have Both Comments and Descriptions? Which One Should I Use and When?
Here’s how we think about this: the description, which you can put after each keyword,
is part of the structured Gherkin document and is the right place to put documentation
for your stakeholders.
Comments, on the other hand, can be used more to leave notes for testers and programmers who are working with the features. Think of a comment as something more
temporary, a bit like a sticky note.
Don’t forget that programmers and testers need documentation too. If there are
technical details that need to be documented with the feature, you should feel free
to put them into the description too, provided that the business-facing members of
your team are comfortable with it being there.
If you’re wondering whether Cucumber knows how to speak your language,
you can ask it for the list of all valid languages with this command:
$ cucumber --i18n help
When you’re working with a particular language, you can discover the keywords by passing the language code (as listed by the previous command) to
the --i18 switch. Here’s Japanese, for example:
$ cucumber --i18n ja
One of the greatest benefits of working with a tool like Cucumber is the conversations you have with your stakeholders as you write the scenarios. These
conversations can help you find gaps and misunderstandings that otherwise
might have emerged only after you’d spent days or even weeks working on
the code. So, even if you never run the tests, just writing them can help make
you go faster.
3.7
What We Just Learned
Let’s review what we’ve talked about in this chapter:
• We saw how the core Gherkin keywords Feature, Scenario, Given, When, and
Then can be used to describe the behavior your stakeholders want as
concrete examples.
• There is a fundamental pattern to each Gherkin scenario, with a context
(Given), an event (When), and an outcome (Then).
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• Chapter 3. Gherkin Basics
Joe asks:
So, Can I Mix Spoken languages in My Features?
A project can have a mix of features that use different spoken languages, yes. However,
remember that the setting is for a feature, so all the scenarios in a feature have to
use the same spoken language.
• Each scenario must be capable of being run on its own and should not
depend on data set up by other scenarios. This means every scenario has
to include enough Given steps to set up all the data it needs.
• You can add descriptions and comments to your .feature files to turn them
into useful documentation of your system.
• Using the #language: header, you can write your features in different spoken
languages.
At this point you have all the knowledge you need to get started writing your
own Gherkin features. Even though there are some keywords we haven’t
covered yet, there’s a huge amount of value in what you already know. Just
pretend you have a machine that can turn your Cucumber scenarios into
perfect working code, and play the game of working with your team to create
the best descriptions you can of what you want the software to do.
In the next chapter, we’ll start to explore step definitions, the layer beneath
the Gherkin features where you interact with your application, and bring
your scenarios to life.
Try This
Here are some exercises for you to try.
Practice Given/When/Then
Let’s build a robot! Here’s a scenario:
Scenario: Tickle a happy robot
Given I am in a good mood
When you tickle me
Then I will giggle
What happens if you change the context in which this scenario happens?
Write another scenario where the first step puts the robot into a bad mood.
Leave the action the same. What will be the outcome when you tickle a grumpy
robot?
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What We Just Learned
• 37
Now try changing the action:
Scenario: Attack a happy robot
Given I am in a good mood
When you kick me in the shins
Then I will ...
What will the outcome be now?
Your First Scenario
Write the first formal Gherkin scenario for your project. Pick a feature you’re
working on right now, and try to describe the way the system should behave
when you’re done. Notice when you have questions about the precise language
you should use, or the precise behavior, and write down those questions. Try
to get some time with the right people on your team to answer those questions.
Show them the scenario: does it make sense to them? How would they have
worded it?
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CHAPTER 4
Step Definitions: From the Outside
Now that you know how to use Gherkin to describe what you want your tests
to do, the next task is to tell them how to do it. Whether you choose to drive
your acceptance tests from Cucumber scenarios or simple Test::Unit scripts,
there’s no escaping the fact that you’re going to need to write some code
eventually. It’s about that time.
Step definitions sit right on the boundary between the business’s domain and
the programmer’s domain. They’re written in Ruby,1 and their responsibility
is to translate each plain-language step in your Gherkin scenarios into concrete actions in Ruby code. As an example, take this step from the ATM
scenario in the previous chapter:
Given I have $100 in my Account
The step definition for this step needs to make the following things happen:
• Create an account for the protagonist in the scenario (if there isn’t one
already).
• Set the balance of that account to be $100.
How exactly those two goals are achieved depends a great deal on your specific application. Automated acceptance tests generally try to simulate user
interactions with the system, and the step definitions are where you’ll tell
Cucumber how you want it to poke around with your system. That might
involve clicking buttons on a user interface or reaching beneath the covers
and directly inserting data into a database, writing to files, or even calling a
web service. We think of step definitions themselves as distinct from the
1.
In fact, Cucumber supports step definitions written in many other programming languages too, but we’re concentrating on Ruby in this book.
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automation code that does the actual poking so that the layers separate out
like Figure 3, Step definitions are translators, on page 41.
There are two sides to a step definition. On the outside, it translates from
plain language into Ruby, and on the inside it tells your system what to do
using Ruby automation code. Ruby has an incredibly rich set of libraries for
automating a whole variety of systems, from JavaScript-heavy web applications
to REST web services. We’re not going to show you how to use all of those
libraries in this chapter; that will come later in the book. Here we’re going to
concentrate on the main responsibility of this layer of your Cucumber tests,
which is to interpret a plain-language Gherkin step and decide what to do.
We’re going to start by explaining some of the mechanics of how step definitions match up to plain-language steps and then work through an example
of how to write a single step definition that can handle many different steps.
We’ll finish off by explaining how Cucumber executes step definitions and
deals with their results. When we’re done, you should understand enough to
start writing and running your own step definitions.
4.1
Steps and Step Definitions
Let’s start by clarifying the distinction between a step and a step definition.
Each Gherkin scenario is made up of a series of steps, written in plain language. On its own, a step is just documentation; it needs a step definition to
bring it to life. A step definition is a piece of Ruby code that says to Cucumber,
“If you see a step that looks like this…, then here’s what I want you to do….”
When Cucumber tries to execute each step, it looks for a matching step definition to execute. So, how does Cucumber match a step definition to a step?
Matching a Step
Gherkin steps are expressed in plain text. Cucumber scans the text of each
step for patterns that it recognizes, which you define using a regular expression. If you haven’t used regular expressions before, then just think of them
like a slightly more sophisticated version of the wildcards you’d use to search
for a file. Although they can look intimidating at first, there are actually only
a small number of patterns you need to get a great deal of mileage out of
them. All of those patterns will be covered in this chapter; if you’re already
well familiar with regular expressions, you might want to skim over the next
few sections, up until Section 4.5, Returning Results, on page 52.
Let’s take the ATM example from the previous chapter:
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Steps and Step Definitions
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Gherkin Features
What to do
Step Definitions
How to do it
Ruby Automation
Code
Do this now!
System Under Test
Figure 3—Step definitions are translators.
Download step_definitions/intro/features/cash_withdrawal.feature
Feature: Cash withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have $100 in my account
When I request $20
Then $20 should be dispensed
As Cucumber executes this feature, it will come to the first step of the scenario,
Given I have $100 in my Account and say to itself, Now, do I have any step definitions
that match the phrase I have $100 in my Account?
A simple regular expression that will match this step would look like this:
/I have \$100 in my Account/
In Ruby, regular expressions are denoted by those forward slashes. Notice
that we’ve had to escape the dollar sign with a backslash. That’s because the
dollar sign can have a special meaning in a regular expression, but in this
case we want to interpret it literally. We’ll come back to these special characters a bit later in the chapter.
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Aslak says:
Avoiding Regular Expressions
Cucumber allows you to define step definitions using strings instead of regular
expressions. This might seem simpler at first, but it has other problems, which I’ll
illustrate with an example. Here is a step definition that uses a plain string:
Given "I have 100 in my Account" do
end
We couldn’t write $100 here, because the $ has a special meaning when you define
step definitions with strings. Any $ signs—including any letter or number following
it—will be interpreted as an argument, which you will learn more about in Section
4.2, Capturing Arguments, on page 45. This step definition uses an argument:
Given "I have $amount in my Account" do |amount|
end
This step definition would match both of the following Gherkin steps:
Given I have 100 in my Account
Given I have $100 in my Account
In the first case, the step definition’s amount argument would have the value "100". In
the second case, it would have the value "$100". If our step definition expects a string
with only digits, this can be problematic. We have no way to enforce a consistent way
to write Gherkin steps, and the step definitions have to anticipate many kinds of input.
This is why using strings instead of regular expressions is not as advantageous as
you might think. They give far less control over what gets matched and what arguments a step definition can receive.
If Cucumber sees a step definition with this regular expression, it will execute
it when it comes to the first step of our scenario. So, how do we create a step
definition?
Creating a Step Definition
Step definitions live in regular Ruby files in the features/step_definitions folder. To
create a step definition, you can use the special Cucumber method Given, like
this:
Given /I have \$100 in my Account/ do
# TODO: code that puts $100 into User's Account goes here
end
You’ll typically put several step definitions like this together in the same Ruby
file. Cucumber will load all the files in the features/step_definitions directory, so
it’s really up to you how exactly you want to organize them. We suggest
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Steps and Step Definitions
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keeping a separate file per domain entity so that step definitions that work
with similar parts of the system are kept together.
Let’s examine the step definition in detail. This is a Ruby file, and we’re calling
the special Cucumber method Given, which tells Cucumber that we want to
register a step definition. We pass the Given method two things: a regular
expression to match one or more steps (the bit between the forward slashes)
and a block of Ruby code (the bit between the do...end) to execute if it does.
Cucumber stores the code block for later to execute if it comes across a
matching step.
You can also use the methods When or Then to create a step definition in just
the same way.
Given, When, Then Are the Same
It doesn’t actually matter which of the three methods you use to register a
step definition, because Cucumber ignores the keyword when matching a
step. Under the hood, all of the keyword methods are aliases for Cucumber::
RbDsl#register_rb_step_definition. The keywords are really just there for extra documentation to help you express the intent of each step or step definition.
This means that, whether it was created with the method Given, When, or Then,
a step definition will match any Gherkin step as long as the regular expression
matches the main text of the step. Figure 4, Cucumber ignores keywords when
matching a step, on page 44 highlights what Cucumber sees when it scans a
scenario for matching step definitions.
This flexibility can be really handy, as we’ll show you later, but there is one
gotcha to watch out for. Let’s take a look at an example.
Imagine you have already implemented your ATM withdrawal scenario, including writing a step definition for Given I have $100 in my Account. So, you have a step
definition that matches the text I have $100 in my Account and creates an account
with $100 in it. A few weeks later that scenario is a dim and distant memory,
and you get a new requirement to give all new accounts a $1 gift. You sit
down with your domain expert and write the following scenario:
Scenario: New accounts get a $1 gift
Given I have a brand new Account
And I deposit $99
Then I have $100 in my Account
That looks reasonable, doesn’t it? We set up the new account, deposit some
money, and then check that the new balance is what we’d expect it to be. But
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Feature: Cash Withdrawal
Scenario: Attempt withdrawal using stolen card
Given I have $100 in my account
But my card is invalid
When I request $50
Then my card should not be returned
And I should be told to contact the bank
Figure 4—Cucumber ignores keywords when matching a step.
can you see what’s going to happen if we run this new scenario together with
our original ATM withdrawal scenario?
Let’s look at our original step definition again:
Given /I have \$100 in my Account/ do
# TODO: code that puts $100 into User's Account goes here
end
Now that we’ve learned that Cucumber ignores the Given/When/Then keyword
when matching a step, we can see that this original step definition is also
going to match the last step of our new scenario, Then I have $100 in my Account.
Surprise! We expected that step to check the balance of the account, but instead it’s going to put $100 into the account!
You obviously need to be careful in this situation, because we could easily
have had a scenario that was giving us a false positive: passing when it should
have been failing. It might not seem like it, but Cucumber’s flexibility has
actually helped us here, by exposing some quite subtle ambiguity in the language used in each of the steps. The best way we’ve found to avoid this kind
of problem is to pay careful attention to the precise wording in your steps.
You could change both steps to be less ambiguous:
Given I have deposited $100 in my Account
Then the balance of my Account should be $100
By rewording the steps like this, you’ve made them better at communicating
exactly what they will do when executed. Learning to spot and remove this
kind of ambiguity is something that takes practice. Paying attention to the
distinction in wording between two steps like this can also give you hints
about concepts that may not be expressed in your code but need to be. It
might seem pedantic, but we’ve found that teams who pay this much careful
attention to detail write much better software, faster.
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Capturing Arguments
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Speaking in Tongues
If you’re using a different spoken language than English in your features, you
can still use the same language when registering step definitions. Cucumber
creates an alias of Cucumber::RbDsl#register_rb_step_definition for every spoken language, so a team working in Spain, for example, could use the following:
Dado /tengo \$100 en mi Cuenta/ do
# TODO: code that puts $100 into User's Account goes here
end
Remember, you can discover the keywords for your spoken language using
the command cucumber --i18n <language>.
4.2
Capturing Arguments
You’ll notice that in the step we’ve been using as an example, we’ve talked
about the sum of $100 the whole time. What if we had another scenario where
we needed to deposit a different amount of money into the account? Would
we need another step definition, like this?
Given /I have deposited \$100 in my Account/ do
# TODO: code goes here
end
Given /I have deposited \$250 in my Account/ do
# TODO: code goes here
end
Happily, we don’t. This is where the flexibility of regular expressions comes
into play. We can use two of regular expressions’ most useful features here
to capture any dollar amount as an argument to the step definition. Those
features are capture groups and wildcards.
Capture Groups
When you surround part of a regular expression with parentheses, it becomes
a capture group. Capture groups are used to highlight particular parts of a
pattern that you want to lift out of the matching text and use. In a Cucumber
step definition, the text matched within each capture group is passed to the
code block as an argument:
Given /I have deposited \$(100) in my Account/ do |amount|
# TODO: code goes here
end
Here the block argument amount will receive the string value 100 when this
step definition matches. The previous example is a bit silly, because this
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regular expression is still only ever going to match steps that talk about the
amount of $100. We need to use a wildcard inside the capture group to open
it up to other values.
Alternation
There are a few different ways to specify a wildcard in a regular expression.
One of the simplest is alternation, where we express different options separated
by a pipe character |, like this:
Given /I have deposited \$(100|250) in my Account/ do |amount|
# TODO: code goes here
end
This step definition will now match a step with either of the two values 100 or
250 in it, and the number will be captured and passed to the block as an
argument. Alternation can be useful if there are a fixed set of values that you
want to accept in your step definition, but normally you’ll want something a
little looser.
The Dot
The dot is a metacharacter, meaning it has magical powers in a regular
expression. Literally, a dot means match any single character. So, we can try
this instead:
Given /I have deposited \$(...) in my Account/ do |amount|
# TODO: code goes here
end
That will now match a step with any three-figure dollar sum and send the
matched amount into the block. This is definitely a step in the right direction,
but there are a couple of problems with what we’ve done. For one, remember
that the dot matches any character, so we could end up capturing letters in
here instead of numbers. More importantly, what if we wanted a step that
deposits just $10 in the account, or $1,000? This step definition won’t match
those steps because it’s always looking for three characters. We can fix this
by using a modifier.
The Star Modifier
In regular expressions, a repetition modifier takes a character (or metacharacter) and tells us how many times over it can appear. The most flexible modifier
is the star:
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Joe asks:
What If I Actually Want to Match a Dot?
Any of the metacharacters like the dot can be escaped by preceding them with a
backslash. So, if you wanted to specifically match, say 3.14, you could use /3\.14/.
You might have noticed that there’s a backslash in front of the dollar amount in the
step definition we’re using. That’s because $ itself is a metacharacter (it’s an anchor,
which we’ll explain later), so we need to escape to make it match a normal dollar sign.
Given /I have deposited \$(.*) in my Account/ do |amount|
# TODO: code goes here
end
The star modifier means any number of times. So, with .* we’re capturing any
character, any number of times. Now we’re getting somewhere. This will definitely allow us to capture all those different amounts. But there’s still a
problem.
The star modifier is a bit of a blunt instrument. Because we’re using it with
the dot that matches any character, it will gobble up any text at all up until
the phrase in my Account. This is why, in regex terminology, the star modifier
is known as a greedy operator. For example, it would happily match this step:
Given I have deposited $1 and a cucumber in my Account
Ridiculously, the amount argument captured by our regular expression in this
case would be 1 and a cucumber. We need to be a bit more specific about the
characters we want to match so that we just capture numbers. Instead of a
dot, we can use something else.
Character Classes
Character classes allow you to tell the regular expression engine to match
one of a range of characters. You just place all of the characters you would
accept inside square brackets:
Given /I have deposited \$([0123456789]*) in my Account/ do |amount|
# TODO: code goes here
end
For a continuous range of characters like we have, you can use a hyphen:
Given /I have deposited \$([0-9]*) in my Account/ do |amount|
# TODO: code goes here
end
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Now we’ve restricted the character we’ll accept to be numeric. We’re still
modifying the character with the star to accept any number of them, but we’re
now being specific that we’ll accept only a continuous string of numbers.
Shorthand Character Classes
For common patterns of characters like [0-9], there are a few shorthand character classes that you can use instead. You may find this just makes your
regular expressions more cryptic, but there are only a few to learn. For a
digit, you can use \d as a shorthand for [0-9]:
Given /I have deposited \$(\d*) in my Account/ do |amount|
# TODO: code goes here
end
See Useful Shorthand Character Classes, on page 49 for more examples.
There’s just one last problem with this. Can you see what it is?
The Plus Modifier
The star is one example of a repetition modifier, but there are others. A subtle
problem with the star is that any number of times can mean zero.
So, this step would match:
Given I have deposited $ in my Account
That’s no good. To fix this, we can use the + modifier, which means at least
once:
Given /I have deposited \$(\d+) in my Account/ do |amount|
# TODO: code goes here
end
There we go. We took a rambling route to get to the answer, but on the way
we’ve visited almost every one of the features of regular expressions that are
useful to us when building Cucumber step definition. There are only a couple
more to cover.
Try This
Imagine you’re building a system for airport departure lounge screens. You
need to be able to capture examples of flight codes from the Cucumber scenarios. Can you write a single step definition that can capture the flight codes
from all of these steps?
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Multiple Captures
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Useful Shorthand Character Classes
Here are the most useful shorthand character classes:
\d
stands for digit, or [0-9].
\w
stands for word character, specifically [A-Za-z0-9_]. Notice that underscores and
digits are included but not hyphens.
\s
stands for whitespace character, specifically [ \t\r\n]. That means a space, a tab,
or a line break.
\b
stands for word boundary, which is a lot like \s but actually means the opposite
of \w. Anything that is not a word character is a word boundary.
You can also negate shorthand character classes by capitalizing them, so for example,
\D means any character except a digit.
Given the flight EZY4567 is leaving today
...
Given the flight C038 is leaving today
...
Given a flight BA01618 is leaving today
Start by writing a step definition that works for the first step, and then make
it more and more generic so that it works with the other steps too.
4.3
Multiple Captures
You don’t have to stop at capturing just a single argument. Cucumber will
pass an argument to your block for every capture group in your regular
expression, so you can grab as many details as you like from a step.
Here’s an example. Let’s imagine our bank wants to start offering its customers
savings accounts as well as their regular checking account. Customers can
use the ATM to transfer money between their accounts. Here’s one of the
scenarios for this new feature:
Scenario: Transfer funds from savings into checking account
Given I have deposited $10 in my Checking Account
And I have deposited $500 in my Savings Account
When I transfer $500 from my Savings Account into my Checking Account
Then the balance of the Checking Account should be $510
And the balance of the Savings Account should be $0
Let’s try to write a step definition that can handle the first two steps. As well
as the amount deposited, we need to capture the type of account so that we
know where to put it.
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We can use a modified version of the regular expression we used previously
to capture the type of account:
Given /I have deposited \$(\d+) in my (\w+) Account/ do |amount, account_type|
# TODO: code goes here
end
We use the shorthand character class \w, modified with the plus to mean any
word character, at least once, effectively capturing a single word. That word
is then passed to the block in the second argument, which we’ve named
account_type.
Try This
Write a step definition for the next step in the scenario, When I transfer $500 from
my Savings Account into my Checking Account. The step definition should capture three
arguments:
• The amount of money being transferred
• The type of account being debited in the transfer
• The type of account that receives the credit in the transfer
Test it by writing simple puts statements in your step definition to print the
value captured in each argument to the console.
4.4
Flexibility
The readability of Cucumber features helps teams learn to use a ubiquitous
language when talking about the system they’re building. This is a really
important benefit, because that consistent use of terminology helps reduce
misunderstandings and allow communication to flow more smoothly between
everyone on the team.
So, we want to encourage our feature authors to be consistent about the
nouns and verbs they use in the Cucumber features, because it helps make
features that can be readily understood by anyone on the team. Equally, we
also want feature authors to be able to express themselves as naturally as
possible, which means they may often use slightly different phrasing to mean
exactly the same thing. This is fine; in fact, it’s to be encouraged. Cucumber
features are all about communicating with business users in their language,
and it’s important that we don’t force them to sound like robots.
To keep the features readable and natural, it’s useful to develop the skill to
make your step definitions flexible enough to match the different ways
something might be expressed by a feature author. This isn’t as hard as you
might think.
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Flexibility
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The Question Mark Modifier
When matching business-facing Gherkin text, you’ll often want to indicate
that you don’t care about the odd character in your match, such as when a
word could be singular or plural:
Given I have 1 cucumber in my basket
Given I have 256 cucumbers in my basket
Like the star and the plus, the question mark modifies the character that
precedes it, specifying how many times it can be repeated. The question mark
modifier means zero or one times; in other words, it makes the preceding
character optional. In step definitions, it’s particularly useful for plurals:
Given /I have (\d+) cucumbers? in my basket/ do |number|
# TODO: code goes here
end
By putting a question mark after the s in cucumbers, we’re saying that we don’t
care whether the word is singular or plural. So, this step definition will match
both of the previous steps.
You’ll find that the question mark comes in handy to knock off some rough
edges from your step definitions and make them nice and flexible for your
feature authors. Another useful technique is to use a noncapturing group.
Noncapturing Groups
Remember back in Alternation, on page 46 we showed you how you can list
a set of possible values for part of a regular expression, separated by pipe.
We can use this same technique to add flexibility to our step definitions,
allowing feature authors to use slightly different ways to say the same thing.
There’s one little change we’ll need to make, but we’ll get to that in a minute.
Take this extremely common step for a web application:
When I visit the homepage
Suppose someone comes along and writes another step that looks like this:
When I go to the homepage
Both of these steps have identical meaning to the reader, but unfortunately
a step definition for the first one won’t match the second one without some
modification. It would be helpful to have a step definition to recognize both
phrases, because it really doesn’t matter whether you say visit or go to—they
both mean the same thing. We can use an alternate to relax the step definition
to accept this slightly different phrasing:
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When /I (?:visit|go to) the homepage/ do
# TODO: code goes here
end
Notice that we’ve had to prefix the list of alternates with another bit of regular
expression magic. The ?: at the start of the group marks it as noncapturing,
meaning Cucumber won’t pass it as an argument to our block.
Anchors
You might have noticed that the step definition snippets that Cucumber prints
for undefined steps start with a ^ and end with a $. Perhaps you’ve become
so used to seeing them that you’ve stopped noticing them altogether. These
two metacharacters are called anchors, because they’re used to tie down each
end of the regular expression to the beginning and end of the string that they
match on.
You don’t have to use them, and we deliberately left them out of the example
up to this point because we wanted to wait until we’d explained what they
do. If you omit one or both of them, you’ll find you end up with a much more
flexible step definition—perhaps too flexible. As a silly example, suppose we
add the ^ anchor to the beginning but omit the $ at the end of our bank
account step definition:
Given /^I have deposited \$(\d+) in my Account/ do |amount|
# TODO: code goes here
end
This will allow a particularly creative feature author to write something like
this:
Given I have deposited $100 in my Account from a check my Grandma gave to me
Generally, it’s best to keep your regular expressions as tight as you can so
that there’s less chance of two step definitions clashing with each other. That’s
why the snippets that Cucumber generates for undefined steps always include
the anchors. Still, leaving off the anchors is a trick worth knowing about that
can sometimes come in handy.
4.5
Returning Results
Cucumber is a testing tool, and it’s in the Ruby code of a step definition where
our tests find out whether a step has succeeded in whatever it set out to do.
So, how does a step definition tell Cucumber whether it passed or failed?
Like most other testing tools, Cucumber uses exceptions to communicate the
failure of a test. As it executes a scenario, one step at a time, Cucumber
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Returning Results
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Execute
Scenario
rst
step
Do we have a
matching step
nition?
No
Yes
Execute step
nition's code
block
Read next
step
Was an
exception
thrown?
Yes
No
Pending?
Yes
Any more
steps?
No
Yes
Failed
Scenario
Pending
Scenario
No
Passed
Scenario
ned
Scenario
Figure 5—How Cucumber executes a scenario
assumes that a step has passed unless its step definition raises an exception.
If a step passes, it moves on to the next step. Figure 5, How Cucumber executes
a scenario, on page 53 shows how this plays out.
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In Cucumber, results are a little more sophisticated than a simple pass or
fail. A scenario that’s been executed can end up in any of the following states:
•
•
•
•
Undefined
Pending
Failed
Passed
These states are designed to help indicate the progress that you make as you
develop your tests. Let’s run through an example of automating the ATM
withdrawal scenario to illustrate what we mean.
Undefined Steps
When Cucumber can’t find a step definition that matches a step, it marks
the step as undefined (yellow) and stops the scenario. The rest of the steps
in the scenario will be either skipped or marked as undefined too if they don’t
have a matching step definition themselves.
To show you how this works, we can run our ATM withdrawal scenario. Create
a file called features/cash_withdrawal.feature, and put the following into it:
Download step_definitions/00/features/cash_withdrawal.feature
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I request $20
Then $20 should be dispensed
We haven’t written any step definitions yet, so when we run this feature, we
should see the steps all come up as undefined:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I request $20
Then $20 should be dispensed
1 scenario (1 undefined)
3 steps (3 undefined)
0m0.001s
If you have color output in your terminal, you should see each step is yellow,
indicating that it’s neither failing (red) nor passing (green) but somewhere in
between. Notice also that Cucumber has printed out a snippet for each
missing step definition. We can use these as a starting point for implementing
our own step definitions.
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Assertions and Exceptions
Even if you’re used to using a testing library like Test::Unit or RSpec, you might not have
realized that the assertions in those libraries work by raising exceptions.
You can prove this to yourself by writing a little Ruby program that runs a failing
assertion:
Download step_definitions/assertions_sidebar/assertion.rb
require 'test/unit/assertions'
include Test::Unit::Assertions
begin
assert false, "Hello World"
rescue Exception => exception
puts "Exception was raised: #{exception.class}"
end
When you run it, you should find that this program raises an exception of type
MiniTest::Assertion (or a Test::Unit::AssertionFailedError if you’re using Ruby 1.8)
Pending Steps
When Cucumber discovers a step definition that’s halfway through being
implemented, it marks the step as pending (yellow). Again, the scenario will
be stopped, and the rest of the steps will be skipped or marked as undefined.
How does Cucumber know whether a step definition has been implemented?
Of course, you have to tell it. A few special Cucumber methods are available
from within your step definitions’ code blocks (which we’ll talk about more
in Chapter 7, Step Definitions: On the Inside, on page 111); one of them is
pending.
When you call pending from within a step definition, it raises a Cucumber::Pending error. This tells Cucumber’s runtime that the step has failed but in a
particular way: the step definition is still being worked on. You’ll probably
have noticed that the snippets Cucumber generates for undefined steps have
a call to pending in them; now you understand why.
Let’s get back to our ATM withdrawal scenario to show you what we mean.
Create a file called features/step_definitions/steps.rb and paste in this step definition:
Download step_definitions/01/features/step_definitions/steps.rb
Given /^I have deposited \$(\d+) in my account$/ do |amount|
pending("Need to design the Account interface")
end
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• Chapter 4. Step Definitions: From the Outside
Now when we run cucumber, we’ll see that it has only tried to execute the first
step and has marked it as pending. All the rest are still undefined:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
Need to design the Account interface (Cucumber::Pending)
./features/step_definitions/steps.rb:2
features/cash_withdrawal.feature:3
When I request $20
Then $20 should be dispensed
1 scenario (1 pending)
3 steps (2 undefined, 1 pending)
0m0.002s
The pending status is bit like those under construction signs you used to see
all over the Internet in the 1990s. You can use it as a temporary signpost to
your teammates that you’re in the middle of working on something.
When we’re developing a new scenario from the outside-in like this, we’ll tend
to work right across the same layer before diving into the next one. Right now
we’re concentrating on adding step definitions, so let’s do that for each of the
other steps and add a pending call in each one:
Download step_definitions/02/features/step_definitions/steps.rb
Given /^I have deposited \$(\d+) in my account$/ do |amount|
pending("Need to design the Account interface")
end
When /^I request \$(\d+)$/ do |amount|
pending("How do we simulate cash being requested?")
end
Then /^\$(\d+) should be dispensed$/ do |amount|
pending("How do we validate that cash was dispensed?")
end
As we do this, we can check to see whether there are any existing step definitions we could use and, if not, just create a new one with a call to pending. The
pending scenarios become our to-do list for the work we’ll do when we drop
down to the next layer and start implementing the step definitions.
Failing Steps
If the block of code executed by a step definition raises an exception, Cucumber will mark that step as failed (red) and stop the scenario. The rest of the
steps in the scenario will be skipped.
In practice, there are two reasons why a step definition will fail:
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Returning Results
• 57
Strict Mode
If you use the --strict command-line option, cucumber will return an exit code of 1 (to
indicate an error) if there are any undefined or pending steps.
This can be useful in a continuous integration build to spot any half-finished features
that have been accidentally checked in or when you’ve refactored your step definitions
and some of your steps are no longer matching.
• The scenario couldn’t finish because you have a bug in your step definition
code, or in the system under test, which has caused it to throw an error.
You’ll get used to seeing these failures all the time during development if
you use Cucumber to drive your development from the outside-in. Each
failure message tells you what you need to do next.
• The step definition has used an assertion to check something about the
state of the system, and the check didn’t pass. You’ll typically get these
errors right at the end of your outside-in cycle or long after the feature
has been implemented if someone accidentally introduces a bug.
An assertion is a check in your tests that describes some condition that you
expect to be satisfied. Failures because of assertions tend to happen in Then
steps, whose job is to check things about the state of the system. These are
the alarm bells you’re fitting to the system that will go off if it starts to behave
in unexpected ways. Either way, Cucumber will show you the exception
message and backtrace in its output, so it’s up to you to investigate.
We’re almost done with this chapter, but we want to show you an example
of a failing step first. We’re at the point where we need to start designing the
interface between our tests and our system. Let’s start with something simple
and imagine an Account class that we can use to create a bank account for the
actor in our scenario. We can modify the step definition like this:
Download step_definitions/03/features/step_definitions/steps.rb
Given /^I have deposited \$(\d+) in my account$/ do |amount|
Account.new(amount.to_i)
end
What’s going to happen when we run this? We don’t actually have an Account
class, so it’s going to blow up:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
uninitialized constant Account (NameError)
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./features/step_definitions/steps.rb:3
features/cash_withdrawal.feature:3
When I request $20
Then $20 should be dispensed
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
3 steps (1 failed, 2 skipped)
0m0.002s
What’s this failure telling us? It’s telling us we need to create an Account class,
of course! We’re not going to start building our banking system right now,
but we’ll pick this example up again in Chapter 7, Step Definitions: On the
Inside, on page 111. As you’ve seen, Cucumber has caught the exception and
displayed it to us just beneath the step. In the summary at the bottom we
can see that the step failed, and the rest were skipped.
4.6
What We Just Learned
It’s useful to think of a step definition as being a special kind of method.
Unlike a regular Ruby method, whose name has to match exactly, a step
definition can be invoked by any step that matches its regular expression.
Because regular expressions can contain wildcards, this means you have the
flexibility to make the Gherkin steps nice and readable, while keeping your
Ruby step definition code clean and free of duplication.
• Step definitions provide a mapping from the Gherkin scenarios’ plainlanguage descriptions of user actions into Ruby code, which simulates
those actions.
• Step definitions are registered with Cucumber by calling Given, When, Then,
or one of the aliases for your spoken language.
• Step definitions use regular expressions to declare the steps that they
can handle. Because regular expressions can contain wildcards, one step
definition can handle several different steps.
• A step definition communicates its result to Cucumber by raising, or not
raising, an exception.
Now that you’ve seen how Gherkin and step definitions fit together, you’re
ready to start using Cucumber to test your own applications. To get your step
definitions talking to the application, you’ll need to learn how to use one of
Ruby’s automation libraries, many of which are covered in the recipes part
of this book. If you’re testing a web application, for example, see Chapter 15,
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What We Just Learned
• 59
Using Capybara to Test Ajax Web Applications, on page 245, and if your web
application runs on Ruby on Rails, see Chapter 14, Bootstrapping Rails, on
page 229. If you want to test a command-line application, try Chapter 16,
Testing Command-Line Applications with Aruba, on page 275. Web services are
covered in Chapter 12, Testing a REST Web Service, on page 201.
Over here in the fundamentals part, we’re going to start putting some more
flesh on the bones of your Cucumber knowledge. There’s much more to
Gherkin than the basic keywords we taught you in the previous chapter, and
that’s what we’ll explore next.
Try This
At the end of the previous chapter, we suggested that you write some scenarios
for your own project. Now try running them with Cucumber and use the
snippets to create your first step definitions. Think about which domain entity
each step is working with, and use that to decide which file to put the step
definition into. Look for places you can use what you’ve learned about regular
expressions to make the step definitions more flexible.
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• Chapter 4. Step Definitions: From the Outside
Matt says:
Choosing Your Assertion Library
When making assertions in Cucumber step definitions, there are a few different
libraries you could choose. The main candidates are RSpec,a MiniTest,b and Wrong.c
We’ll give you a quick overview of each one’s strengths, and you can choose your
favorite. Here’s a quick example of each of them in use:
# MiniTest
>> require 'test/unit'
>> include Test::Unit::Assertions
>> assert_equal 'green', 'cucumber'
MiniTest::Assertion: <"green"> expected but was
<"cucumber">.
# RSpec
>> require 'rspec/expectations'
>> "green".should == "cucumber"
RSpec::Expectations::ExpectationNotMetError: expected: "cucumber"
got: "green" (using ==)
# Wrong
>> require 'wrong'
>> include Wrong
>> assert { 'green' == 'cucumber' }
Wrong::Assert::AssertionFailedError: Expected ("green" == "cucumber"), but
Strings differ at position 0:
first: "green"
second: "cucumber"
MiniTest’s assertions are built into Ruby, which makes them a handy tool to reach
for. They use a style of assertion that you’ll be familiar with if you’re used to making
assertions in any xUnit testing framework.
RSpec’s assertions are automatically loaded by Cucumber. Their style emphasizes
readability.
Wrong is a new kid on the block. It uses Ruby magic tricks to read the code you’ve
passed to the assertion to produce really helpful error messages.
In the end, the choice is a personal preference as to which syntax you prefer; all of
the libraries provide roughly the same set of functionality.
a.
b.
c.
The RSpec Book [CADH09]
http://rubydoc.info/gems/minitest/2.6.1/MiniTest/Assertions
http://rubydoc.info/gems/wrong/0.6.0/frames
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CHAPTER 5
Expressive Scenarios
In Chapter 3, Gherkin Basics, on page 25, we deliberately didn’t give you the
whole story and showed you just a core set of keywords instead. They’re the
fundamental building blocks you need to get started working with Cucumber,
and we wanted to get you started as quickly as possible. Now it’s time to refine
your skills.
When you’re writing Cucumber features, make readability your main goal.
Otherwise, a reader can easily feel more like they’re a reading computer program than a specification document, which is something we want you to try
to avoid at all costs. After all, if your features aren’t easy for nonprogrammers
to read, you might as well just be writing your tests in plain old Ruby code.
The real key to expressive scenarios is having a healthy vocabulary of domain
language to use to express your requirements. That said, using only the basic
set of Gherkin keywords can often make your features repetitive, making
them cluttered and awkward to read. By the end of this chapter you’ll know
everything there is to know about Gherkin’s syntax, giving you all the tools
you need to write clear, readable Cucumber acceptance tests. We’ll also show
you how to use tags and folders to stay organized as you write more features
for your project.
First we want to concentrate on helping you remove that repetitive clutter.
We’re going to show you how to use scenario outlines and data tables to help
make your Gherkin scenarios more readable, but we’ll start with a new keyword called Background.
5.1
Background
A background section in a feature file allows you to specify a set of steps that
are common to every scenario in the file. Instead of having to repeat those
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• Chapter 5. Expressive Scenarios
steps over and over for each scenario, you move them up into a Background
element. There are a couple of advantages to doing this:
• If you ever need to change those steps, you have to change them in only
one place.
• The importance of those steps fades into the background so that when
you’re reading each individual scenario, you can focus on what is unique
and important about that scenario.
To show you what we mean, let’s take an existing scenario that uses only the
basic Gherkin Scenario element and improve its readability by refactoring it to
use a Background. Here’s our feature before the refactoring starts:
Feature: Change PIN
Customers being issued new cards are supplied with a Personal
Identification Number (PIN) that is randomly generated by the
system.
In order to be able to change it to something they can easily
remember, customers with new bank cards need to be able to
change their PIN using the ATM.
Scenario: Change PIN successfully
Given I have been issued a new card
And I insert the card, entering the correct PIN
When I choose "Change PIN" from the menu
And I change the PIN to 9876
Then the system should remember my PIN is now 9876
Scenario: Try to change PIN to the same as before
Given I have been issued a new card
And I insert the card, entering the correct PIN
When I choose "Change PIN" from the menu
And I try to change the PIN to the original PIN number
Then I should see a warning message
And the system should not have changed my PIN
You can see that there are two scenarios here, but without reading them
carefully, it’s quite hard to see what exactly is going on in each one. The first
three steps in each scenario, while necessary to clarify the context of the
scenario, are completely repeated in both scenarios. That repetition is distracting, making it harder to see the essence of what each scenario is testing.
Let’s factor out the three repeated steps into a Background, like this:
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Background
• 63
Feature: Change PIN
As soon as the bank issues new cards to customers, they are
supplied with a Personal Identification Number (PIN) that
is randomly generated by the system.
In order to be able to change it to something they can easily
remember, customers with new bank cards need to be able to
change their PIN using the ATM.
Background:
Given I have been issued a new card
And I insert the card, entering the correct PIN
And I choose "Change PIN" from the menu
Scenario: Change PIN successfully
When I change the PIN to 9876
Then the system should remember my PIN is now 9876
Scenario: Try to change PIN to the same as before
When I try to change the PIN to the original PIN number
Then I should see a warning message
And the system should not have changed my PIN
Our refactoring hasn’t changed the behavior of the tests at all: at runtime,
the steps in the background are executed at the beginning of each scenario,
just as they were before. What we have done is made each individual scenario
much easier to read.
You can have a single Background element per feature file, and it must appear
before any of the Scenario or Scenario Outline elements. Just like all the other
Gherkin elements, you can give it a name, and you have space to put a multiline description before the first step. For example:
Feature: Change PIN
In order to be able to change it to something they can easily
remember, customers with new bank cards need to be able to
change their PIN using the ATM.
Background: Insert a newly issued card and sign in
Whenever the bank issues new cards to customers, they are supplied
with a Personal Identification Number (PIN) that is randomly
generated by the system.
Given I have been issued a new card
And I insert the card, entering the correct PIN
...
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Using a Background element isn’t always necessary, but it’s often useful to
improve the readability of your features by removing repetitive steps from
individual scenarios. Here are some tips for using it well:
• Don’t use Background to set up complicated state unless that state is
something the reader actually needs to know. For example, we didn’t
mention the actual digits of the system-generated PIN in the previous
example, because that detail wasn’t relevant to any of the scenarios.
• Keep your Background section short. After all, you’re expecting the user to
actually remember this stuff when reading your scenarios. If the background is more than four lines long, can you find a way to express that
action in just one or two steps?
• Make your Background section vivid. Use colorful names and try to tell a
story, because your reader can keep track of stories much better than
they can keep track of dull names like User A, User B, Site 1, and so on.
If it’s worth mentioning at all, make it really stand out.
• Keep your scenarios short, and don’t have too many. If the Background is
more than three or four steps long, think about using higher-level steps
or splitting the feature file in two. You can use a background as a good
indicator of when a feature is getting too long: if the new scenarios you
want to add don’t fit with the existing background, consider splitting the
feature.
• Avoid putting technical details such as clearing queues, starting backend
services, or opening browsers in a background. Most of these things will
be assumed by the reader, and there are ways to push those actions down
into your support code that we’ll explain later in the book, such as in
Tagged Hooks, on page 147.
Backgrounds are useful for taking Given (and sometimes When) steps that are
repeated in each scenario and moving them to a single place. This helps keep
your scenarios clear and concise.
5.2
Data Tables
Sometimes steps in a scenario need to describe data that doesn’t easily fit on
a single line of Given, When, or Then. Gherkin allows us to place these details in
a table right underneath a step. Data tables give you a way to extend a Gherkin
step beyond a single line to include a larger piece of data.
For example, consider these steps:
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Data Tables
• 65
Refactoring to Background
Refactoringa is the process of changing code to improve its readability or design
without changing its behavior. This technique applies to Gherkin features just as
well as it does to the rest of your codebase. As your understanding of your domain
grows through the course of the project, you’ll want to reflect that learning by updating
your features.
Often you don’t see a background immediately. You might start out by writing one
or two scenarios, and it’s only as you write the third that you notice some common
steps. When you spot a feature where the same or similar steps are repeated in several scenarios, see whether you can refactor to extract those steps into a background.
It can take a little bit of courage to do this, because there’s a risk you might make a
mistake and break something, but this is a pretty safe refactoring. Once you’re done,
you should end up with the feature doing exactly the same thing as it did before you
started but easier to read.
a.
Refactoring: Improving the Design of Existing Code [FBBO99]
Given a User "Michael Jackson" born on August 29, 1958
And a User "Elvis" born on January 8, 1935
And a User "John Lennon" born on October 9, 1940
...
Boring! We wouldn’t tolerate this kind of repetitive stuff in a traditional
specification document, and we don’t have to tolerate it in a Cucumber
specification either. We can collect those steps together into a single step that
uses a table to express the data:
Given these Users:
| name
| Michael Jackson
| Elvis
| John Lennon
|
|
|
|
date of birth
August 29, 1958
January 8, 1935
October 9, 1940
|
|
|
|
That’s much clearer. The table starts on the line immediately following the
step, and its cells are separated using the pipe character: |. You can line up
the pipes using whitespace to make the table look tidy, although Cucumber
doesn’t mind whether you do; it will strip out the values in each cell, ignoring
the surrounding whitespace.
In the previous table, we’ve used a heading for each column in the table, but
that’s only because it made sense for that particular step. You have the freedom to specify data in different ways, such as putting the headings down the
side:
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• Chapter 5. Expressive Scenarios
Then I should see
| Wheels
|
| Max Speed
|
| Accessories |
a vehicle that matches the following description:
2
|
60 mph
|
lights, shopping basket |
Or just to specify a list:
Then my shopping list should contain:
| Onions
|
| Potatoes |
| Sausages |
| Apples
|
| Relish
|
To explain how to work with these different shaped tables, we need to take a
short dive down into the step definition layer. If you’re not interested in writing
Ruby step definition code, feel free to skip this bit.
Working with Data Tables in Step Definitions
We’ll illustrate how to use a data table in your step definitions with a quick
game of tic-tac-toe. Let’s imagine we’re building a tic-tac-toe game and we’ve
started working on the basic feature for making moves on the board. We start
with a scenario like this:
Download expressive_scenarios/01/features/tic_tac_toe.feature
Feature:
Scenario:
Given a board like this:
|
| 1 | 2 | 3 |
| 1 |
|
|
|
| 2 |
|
|
|
| 3 |
|
|
|
When player x plays in row 2, column 1
Then the board should look like this:
|
| 1 | 2 | 3 |
| 1 |
|
|
|
| 2 | x |
|
|
| 3 |
|
|
|
We’ll show you how to grab the table from the first step, manipulate it in the
second, and finally compare the expected board from the scenario with the
actual one.
Run cucumber to generate the step definition snippets, and paste them into
features/step_definitions/board_steps.rb:
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Data Tables
• 67
Download expressive_scenarios/01/features/step_definitions/board_steps.rb
Given /^a board like this:$/ do |table|
# table is a Cucumber::Ast::Table
pending # express the regexp above with the code you wish you had
end
When /^player x plays in row (\d+), column (\d+)$/ do |arg1, arg2|
pending # express the regexp above with the code you wish you had
end
Then /^the board should look like this:$/ do |table|
# table is a Cucumber::Ast::Table
pending # express the regexp above with the code you wish you had
end
Notice that the snippets for the two step definitions where we’re going to receive
a table are a little different. There’s a comment telling you that the argument
you’re being passed is a Cucumber::Ast:Table object. That’s a really rich object
with lots of methods for interacting with its data. We’ll show you some of the
most useful ones now.
Let’s start fleshing out those step definitions.
Turning the Table into an Array
Under the hood, the table is just a two-dimensional array. Often we’ll want
to work with it in that raw form, so we can call the raw method on it to do just
that. Let’s get the raw data from the table and store it in an instance variable
@board, which we can manipulate in our second step when we want to make
a move.
As an experiment, add an implementation for the second step definition that
just prints the raw board out so we can see what it looks like:
Download expressive_scenarios/02/features/step_definitions/board_steps.rb
Given /^a board like this:$/ do |table|
@board = table.raw
end
When /^player x plays in row (\d+), column (\d+)$/ do |row, col|
puts @board
pending # express the regexp above with the code you wish you had
end
Then /^the board should look like this:$/ do |table|
# table is a Cucumber::Ast::Table
pending # express the regexp above with the code you wish you had
end
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When you run cucumber, you should see the two-dimensional array is printed
out.
$ cucumber -f progress
.
[["", "1", "2", "3"], ["1", "", "", ""], ["2", "", "", ""], ["3", "", "", ""]]
P(::) pending steps (::)
features/tic_tac_toe.feature:8:in ‘When player x plays in row 2, column 1’
1 scenario (1 pending)
3 steps (1 skipped, 1 pending, 1 passed)
0m0.008s
Notice that the raw table includes the column and row headings.
Comparing Tables with Diff
So that we can start out with a failing test, we’ll skip doing any manipulation
of the board in this step for now. So, remove the body of the second step
definition and make the following implementation in the last step definition:
Download expressive_scenarios/03/features/step_definitions/board_steps.rb
Given /^a board like this:$/ do |table|
@board = table.raw
end
When /^player x plays in row (\d+), column (\d+)$/ do |row, col|
end
Then /^the board should look like this:$/ do |expected_table|
expected_table.diff!(@board)
end
We’ve used the diff! method on the table that describes how things should
look, passing it the actual board as we see it in our application. When you
run cucumber again, you should see that the step has failed because the tables
were not identical:
$ cucumber
Feature:
Scenario:
Given a board
|
| 1 | 2
| 1 |
|
| 2 |
|
| 3 |
|
When player x
like this:
| 3 |
|
|
|
|
|
|
plays in row 2, column 1
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Data Tables
• 69
Then the board should look like this:
|
| 1 | 2 | 3 |
| 1 |
|
|
|
| 2 | x |
|
|
| 2 |
|
|
|
| 3 |
|
|
|
Tables were not identical (Cucumber::Ast::Table::Different)
./features/step_definitions/board_steps.rb:9
features/tic_tac_toe.feature:9
Failing Scenarios:
cucumber features/tic_tac_toe.feature:2
1 scenario (1 failed)
3 steps (1 failed, 2 passed)
0m0.012s
If you have color in your console output, you’ll see the cells that were the
same are green. Expected cells that weren’t found are yellow, and the actual
cells are printed next to them in gray. It’s possible to tweak the comparison
behavior by passing a hash of options to diff!, which you can read about in
the documentation for Cucumber::Ast::Table.
Let’s fix the When step to make the scenario pass. Add this implementation to
the second step definition:
Download expressive_scenarios/04/features/step_definitions/board_steps.rb
When /^player x plays in row (\d+), column (\d+)$/ do |row, col|
row, col = row.to_i, col.to_i
@board[row][col] = 'x'
end
Run the scenario, and you should see it pass.
This is just a taste of what you can do with data tables in Cucumber. We
encourage you to read the documentation2 for Cucumber::Ast::Table and play
around with it yourself.
Data tables are a great feature of Gherkin. They’re really versatile, and they
help you express data concisely, as you’d want to in a normal specification
document. With backgrounds and data tables, you can do a lot to reduce the
noise and clutter in your scenarios. Even when you use these tools, you’ll
still sometimes see a pattern where one scenario looks a lot like the one that
came before it and the one after it. This is where a scenario outline can help.
2.
http://cukes.info/cucumber/api/ruby/latest/Cucumber/Ast/Table.html
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5.3
• Chapter 5. Expressive Scenarios
Scenario Outline
Sometimes you have several scenarios that follow exactly the same pattern
of steps, just with different input values or expected outcomes. For example,
suppose we’re testing each of the fixed amount withdrawal buttons on the
ATM:
Feature: Withdraw Fixed Amount
The "Withdraw Cash" menu contains several fixed amounts to
speed up transactions for users.
Scenario: Withdraw fixed amount of $50
Given I have $500 in my account
When I choose to withdraw the fixed amount of $50
Then I should receive $50 cash
And the balance of my account should be $450
Scenario: Withdraw fixed amount of $100
Given I have $500 in my account
When I choose to withdraw the fixed amount of $100
Then I should receive $100 cash
And the balance of my account should be $400
Scenario: Withdraw fixed amount of $200
Given I have $500 in my account
When I choose to withdraw the fixed amount of $200
Then I should receive $200 cash
And the balance of my account should be $300
Once again, all the repetition in this feature makes it boring to read. It’s hard
to see the essence of each scenario, which is the amount of money involved
in each transaction. We can use a scenario outline to specify the steps once
and then play multiple sets of values through them. Here’s that scenario
again, refactored to use a scenario outline:
Feature: Withdraw Fixed Amount
The "Withdraw Cash" menu contains several fixed amounts to
speed up transactions for users.
Scenario Outline: Withdraw fixed amount
Given I have <Balance> in my account
When I choose to withdraw the fixed amount of <Withdrawal>
Then I should receive <Received> cash
And the balance of my account should be <Remaining>
Examples:
| Balance | Withdrawal | Received | Remaining |
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Scenario Outline
| $500
| $500
| $500
| $50
| $100
| $200
| $50
| $100
| $200
| $450
| $400
| $300
• 71
|
|
|
We indicate placeholders within the scenario outline using angle brackets
(<..>) where we want real values to be substituted. The scenario outline itself
is useless without a table of Examples, which lists rows of values to be substituted for each placeholder.
You can have any number of Scenario Outline elements in a feature and any
number of Examples tables under each scenario outline. Behind the scenes,
Cucumber converts each row in the Examples table into a scenario before executing it. You can prove this to yourself by using the --expand option, which
will print each example in a scenario outline as though it were a scenario:
$ cucumber --expand
One of the advantages of using a scenario outline is that you can clearly see
gaps in your examples. In our example, we haven’t tested any edge cases,
such as when you try to withdraw more money than you have available. This
becomes much more obvious when you can see all the values lined up together
in a table.
Remember that although the syntax for writing them in Gherkin is the same,
these tables are totally different from the data tables we described earlier in
this chapter. Data tables just describe a lump of data to attach to a single
step of a single scenario. In a scenario outline, each row of an Examples table
represents a whole scenario to be executed by Cucumber. In fact, you might
want to use the keyword Scenarios (note the extra s) in place of Examples if you
find that more readable.
Bigger Placeholders
It’s easy to imagine that you can use scenario outline placeholders only where
there’s a piece of data in the step. In fact, when Cucumber compiles a scenario
outline’s table of examples down into scenarios ready to execute, it doesn’t
care where the placeholders are. So, you can substitute as much or as little
as you like from any step’s text.
Let’s illustrate this by testing the edge case where we try to withdraw more
money than we have. What should we do in this case? Give the user as much
as we can, given their remaining balance, or just show them an error message?
We ask our stakeholders for clarification, and they’re happy for us to show
them an error message. Here’s how we write the scenario first:
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Scenario: Try to withdraw too much
Given I have $100 in my account
When I choose to withdraw the fixed amount of $200
Then I should see an error message
And the balance of my account should be $100
There’s still a good deal of duplication here with the flow of the scenarios
above it, but because the Then step is so different, we can’t put this one into
the scenario outline. Or can we?
Let’s change the scenario outline, replacing the <Received> placeholder with a
more abstract <Outcome>:
Scenario Outline: Withdraw fixed amount
Given I have <Balance> in my account
When I choose to withdraw the fixed amount of <Withdrawal>
Then I should <Outcome>
And the balance of my account should be <Remaining>
Examples:
| Balance
| $500
| $500
| $500
|
|
|
|
Withdrawal
$50
$100
$200
|
|
|
|
Remaining
$450
$400
$300
|
|
|
|
Outcome
receive $50 cash
receive $100 cash
receive $200 cash
|
|
|
|
Now we can simply add our failure case to the bottom of that table:
Scenario Outline: Withdraw fixed amount
Given I have <Balance> in my account
When I choose to withdraw the fixed amount of <Withdrawal>
Then I should <Outcome>
And the balance of my account should be <Remaining>
Examples:
| Balance
| $500
| $500
| $500
| $100
|
|
|
|
|
Withdrawal
$50
$100
$200
$200
|
|
|
|
|
Remaining
$450
$400
$300
$100
|
|
|
|
|
Outcome
receive $50 cash
receive $100 cash
receive $200 cash
see an error message
|
|
|
|
|
We can use a placeholder to replace any of the text we like in a step. Notice
that it doesn’t matter what order the placeholders appear in the table: what
counts is that the column header matches the text in the placeholder in the
scenario outline.
Although this is a useful technique, be careful that your programmer’s instinct
to reduce duplication at all costs doesn’t take over here.5 If you move too
5.
See this point explained in detail by David Chelimsky: http://confreaks.net/videos/434.
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Scenario Outline
• 73
Joe asks:
How Many Examples Should I Use?
Once you have a scenario outline with a few examples, it’s very easy to think of more
examples, and even easier to add them. Before you know it, you have a huge, very
comprehensive table of examples—and a problem.
Why?
On a system of any serious complexity, you can quite quickly start to experience what
mathematicians call combinatorial explosion, where the number of different combinations of inputs and expected outputs becomes unmanageable. In trying to cover every
possible eventuality, you end up with rows and rows of example data for Cucumber
to execute. Remember that each of those little rows represents a whole scenario that
might take several seconds to execute, and that can quickly start to add up. When
your tests take longer to run, you slow down your feedback loop, making the whole
team less productive as a result.
A really long table is also very hard to read. It’s better to aim to make your examples
illustrative or representative than exhaustive. Try to stick to what Gojko Adzic calls
the key examples.a If you study the code you’re testing, you’ll often find that some
rows of your examples table cover the same logic as another row in the table. You
might also find that the test cases in your table are already covered by unit tests of
the underlying code. If they’re not, consider whether they should be.
Remember that readability is what’s most important. If your stakeholders feel comforted by exhaustive tests, perhaps because your software operates in a safety-critical
environment, then by all means put them in. Just remember that you’ll never be able
to prove there are no bugs. As logicians say, absence of proof is not proof of absence.
If you’re struggling to pick a representative set from an exhaustive list of examples,
take a look at Joseph Wilk’s pairwiseb Ruby gem.
a.
b.
Specification by Example [Adz11]
https://github.com/josephwilk/pairwise/wiki
much of the text of a step into the examples table, it can be very hard to read
the flow of the scenario. Remember your goal is readability, so don’t take this
too far, and always test your features by getting other people to regularly read
them and give you feedback.
Multiple Tables of Examples
Cucumber will happily handle any number of Examples elements beneath a
Scenario Outline, meaning you can group different kinds of examples together,
if you want. For example:
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Scenario Outline: Withdraw fixed amount
Given I have <Balance> in my account
When I choose to withdraw the fixed amount of <Withdrawal>
Then I should <Outcome>
And the balance of my account should be <Remaining>
Examples: Successful withdrawal
| Balance | Withdrawal | Outcome
| $500
| $50
| receive $50 cash
| $500
| $100
| receive $100 cash
| Remaining |
| $450
|
| $400
|
Examples: Attempt to withdraw too much
| Balance | Withdrawal | Outcome
| Remaining |
| $100
| $200
| see an error message | $100
|
| $0
| $50
| see an error message | $0
|
As usual, you have the option of a name and description for each Examples
table. When you have a large set of examples, splitting it into multiple tables
can make it easier for a reader to understand.
Explain Yourself
You’ll normally be using a scenario outline and examples table to help specify
the implementation of a business rule. Remember to include a plain-language
description of the underlying rule that the examples are supposed to illustrate!
It’s amazing how often people forget to do this.
For example, look at this feature:
Feature: Account Creation
Scenario Outline: Password validation
Given I try to create an account with password "<Password>"
Then I should see that the password is <Valid or Invalid>
Examples:
| Password
| abc
| ab1
| abc1
| abcd
| abcd1
|
|
|
|
|
|
Valid or Invalid |
invalid
|
invalid
|
valid
|
invalid
|
valid
|
If you have to implement the code to make this feature pass, can you tell
what the underlying rule is?
Not very easily. So, let’s modify the feature to make it more self-explanatory,
like this:
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Nesting Steps
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Feature: Account Creation
Scenario Outline: Password validation
Given I try to create an account with password "<Password>"
Then I should see that the password is <Valid or Invalid>
Examples: Too Short
Passwords are invalid if less than 4 characters
| Password | Valid or Invalid |
| abc
| invalid
|
| ab1
| invalid
|
Examples: Letters and Numbers
Passwords need both letters and numbers to be valid
|
|
|
|
Password
abc1
abcd
abcd1
|
|
|
|
Valid or Invalid |
valid
|
invalid
|
valid
|
By separating the examples into two sets and giving each one a name and
description, we’ve explained the rule and given examples of the rule at the
same time.
5.4
Nesting Steps
Finding the right level of detail, or abstraction, to use in your scenarios is a
skill that takes some time to master. What many people don’t realize is that
different levels of detail are appropriate for different scenarios in the same
system—sometimes in the same feature—depending on what it is they’re
describing.
As an example, here’s a scenario for the user of our ATM authenticating with
their PIN:
Scenario: Successful login with PIN
Given I have pushed my card in the slot
When I enter my PIN
And I press "OK"
Then I should see the main menu
It’s entirely appropriate for us to go into this much detail about the authentication process in this scenario, because that’s where our focus is. Now
consider our cash withdrawal scenario from earlier, which has a different focus
but still needs to be authenticated. Does it make sense to express the PIN
authentication steps of this scenario at the same level of detail? Let’s try it:
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Scenario: Withdraw fixed amount of $50
Given I have $500 in my account
And I have pushed my card into the slot
And I enter my PIN
And I press "OK"
When I choose to withdraw the fixed amount of $50
Then I should receive $50 cash
And the balance of my account should be $450
That’s awful! There’s so much noise about authentication that we hardly notice
the important part: the part about withdrawing cash. That detail was useful
in the PIN scenario where it was relevant, but now it’s just distracting. We’ll
talk more about the dangers of over-detailed or imperative scenarios in
Chapter 6, When Cucumbers Go Bad, on page 85; right now we want to show
you a simple refactoring to push these details down into the step definitions
so our scenario is easy to read.
Nest Steps Refactoring
Let’s take the three authentication steps and summarize what they do with
a single high-level step:
Given I have authenticated with the correct PIN
Cut the three lines from the scenario into your clipboard, and replace them
with that single step. Now run cucumber to generate the step definition snippet
for your new high-level step. It should look like this:
Given /^I have authenticated with the correct PIN$/ do
pending # express the regexp above with the code you wish you had
end
Now, use Cucumber’s built-in steps method to call out to the original three
steps in the body of your high-level step’s definition:
Given /^I have authenticated with the correct PIN$/ do
steps %{
And I have pushed my card into the slot
And I enter my PIN
And I press "OK"
}
end
The %{ ... } construct is just a way to tell Ruby that you have a string going
across multiple lines. When Cucumber runs this high-level step, it will delegate
to each of the lower-level steps. So, the behavior of the scenario is exactly the
same, but the language in the business-facing feature is at a higher level.
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Nesting Steps
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Arguments and Nested Steps
If the low-level steps you are nesting within a new high-level step take arguments, you’ll want to be able to capture those arguments in the high-level
step and pass them to the low-level steps. Since the steps method just takes
a string, you can use Ruby’s string interpolation to pass in the arguments:
Given /^an activated customer (\w+) exists$/ do |name|
steps %{
Given I create a customer with login #{name}
And I register the customer with login #{name}
And I activate the customer with login #{name}
}
end
The only time this won’t work is if the argument you’re passing is a data table.
In that case you can use another method, step to call a specific step, passing
the actual typed DataTable object as an argument:
Given /^a (\w+) widget with the following details:$/ do |color, details_table|
step "I create a #{color} widget with the following details:", details_table
steps %{
And I register the #{color} widget
And I activate the #{color} widget
}
end
Nested steps work best when they’re simple: a high-level step delegating to a
few lower-level ones. As soon as you start adding arguments into the mix,
you’re already starting to make things more complicated than they probably
need to be. Remember that underneath it all there are Ruby methods being
called. Often it makes sense to use the Ruby methods directly rather than
obscuring them with layers of nested steps.
The Dangers of Nested Steps
Nested steps are a useful tool to reach for when you need to quickly refactor
an overly detailed scenario to make it more readable. However, you need to
watch out: they can lure you down a path to complexity and frustration.
Here’s a story from Andrew Premdas, an experienced Cucumber user who
once was a big fan of nested steps:
Don’t Use Nested Steps
by: Andrew Premdas
Nested steps are a temptation. They beguile you with the idea that you can achieve something
valuable with great ease. But this is a mirage, because anything you do with nested steps can
be done a simpler way by using Ruby code instead.
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When implementing step definitions, what is important is to make it crystal clear exactly what
you are doing so you can be sure your scenario does what it says, and not something different.
Nested steps allow you to implement step definitions without really knowing what you are doing
or how you are doing it. They put unnecessary layers of obscurity between the scenario and the
code that actually does the work.
Nesting steps prevents you from becoming a better programmer. The programming involved
in implementing step definitions is generally quite simple. Every time you use a nested step you
lose an opportunity to interact directly with the underlying code that talks to your system and
understand how it works. Instead of becoming empowered and learning with each new scenario,
you become more and more dependent on nested steps. As your use of nested steps increases,
this dependency increases, as does the complexity of your step implementations.
The important thing to remember is this: you can apply the extract method refactoring to the body
of every step definition. This choice is always preferable to nesting because it’s always easier to
find, read, and work with a Ruby method call than another step definition. Why bother nesting
when you can extract methods instead?
On our project that used nested steps, the more we nested, the harder it became to implement
scenarios—they just kept breaking for really strange reasons. Getting rid of the nested steps
made things much more transparent. Our colleagues noticed the improvement immediately
and soon were telling us off for nesting steps.
5.5
Doc Strings
Doc strings just allow you to specify a larger piece of text than you could fit
on a single line. For example, if you need to describe the precise content of
an email message, you could do it like this:
Scenario: Ban Unscrupulous Users
When I behave unscrupulously
Then I should receive an email containing:
"""
Dear Sir,
Your account privileges have been revoked due to your unscrupulous behavior.
Sincerely,
The Management
"""
And my account should be locked
Just like a data table, the entire string between the """ triple quotes is attached
to the step above it. The indentation of the opening """ is not important,
although common practice is to indent two spaces in from the enclosing step,
as we’ve shown. The indentation inside the triple quotes, however, is significant: imagine the left margin running down from the start of the first """. If
you want to include indentation within your string, you need to indent it
within this margin.
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Staying Organized with Tags and Subfolders
• 79
Doc strings open up all kinds of possibilities for specifying data in your steps.
We’ve seen teams use these arguments to specify snippets of JSON or XML
data when writing features for an API, for example. There’s an example of
how to do this in Chapter 12, Testing a REST Web Service, on page 201. You
do need to be cautious when including this much detail in a scenario. It’s
easy to create a lot of clutter with a large piece of data, making it hard to read
the scenario as a whole. You can also easily create brittle scenarios, where
the slightest change to the system causes the scenario to fail because it’s
behaving slightly differently than the way it was described in the doc string.
OK, we’ve covered the more advanced features of Gherkin you can use to
express your business requirements. The last thing we want to talk about in
this chapter is keeping things organized.
5.6
Staying Organized with Tags and Subfolders
It’s easy to be organized when you have only a couple of features, but as your
test suite starts to grow, you’ll want to keep things tidy so that the documentation is easy to read and navigate. One simple way to do this is to start using
subfolders to categorize your features. This gives you only one axis for organization, though, so you can also use tags to attach a label to any scenario,
allowing you to have as many different ways of slicing your features as you
like.
Subfolders
This is the easiest way to organize your features. You may find yourself torn
as to how to choose a category, though: do you organize by user type, with
an features/admins folder, a features/logged_in_users folder, and a features/visitors folder,
for example? Or do you organize them by domain entity or something else?
Of course, this is a decision for you and your team to take, but we can offer
a little bit of advice. We’ve had most success using subfolders to represent
different high-level tasks that a user might try to do. So, if we were building
an intranet reporting system, we might organize it like this:
features/
reading_reports/
report_building/
user_administration/
Don’t get too hung up about getting your folder structure right the first time.
Make a decision to try a structure, reorganize all the existing feature files,
and then stick to it for a while as you add new features. Put a note in the
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calendar to take some time out in a couple of weeks and reflect on whether
the new structure is working.
If you think about your features as a book that describes what your system
does, then the subfolders are like the chapters in that book. So, as you tell
the story of your system, what do you want the reader to see when they scan
the table of contents?
Running Features in a Subfolder
If you have put some of your features into subfolders, you can still run them
using the command cucumber, which will automatically find and run all the
.feature files anywhere within the features folder. However, if you want to run
just one feature from a subfolder, there’s a little trick to getting it to work.
Here’s what you might expect to be able to do:
$ cucumber features/reading_reports/widgets_report.feature
# all your steps come up as undefined :(
If you try to run a single feature from a subfolder, you’ll find that all your
steps come up as undefined, even though the step definitions are there in
features/step_definitions. What’s going on? Unfortunately, Cucumber has become
a bit disoriented and no longer knows where to find your step definitions.
You need to tell it explicitly to require the step definition code from the root
features folder:
$ cucumber features/reading_reports/widgets_report.feature -r features
You can use a profile (see Chapter 11, The Cucumber Command-Line Interface,
on page 191) to tell Cucumber to do this automatically.
Tags
If subfolders are the chapters in your book of features, then tags are the sticky
notes you’ve put on pages you want to be able to find easily. You tag a scenario
by putting a word prefixed with the @ character on the line before the Scenario
keyword, like this:
@widgets
Scenario: Generate report
Given I am logged in
And there is a report "Best selling widgets"
...
In fact, you can attach multiple tags to the same scenario, separated with
spaces:
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Staying Organized with Tags and Subfolders
• 81
Aslak says:
Features Are Not User Stories
Long ago, Cucumber started life as a tool called the RSpec Story Runner. In those
days, the plain-language tests used a .story extension. When I created Cucumber, I
made a deliberate decision to name the files features rather than stories. Why did I
do that?
User stories are a great tool for planning. Each story contains a little bit of functionality that you can prioritize, build, test, and release. Once a story has been released,
we don’t want it to leave a trace in the code. We use refactoring to clean up the design
so that the code absorbs the new behavior specified by the user story, leaving it
looking as though that behavior had always been there.
We want the same thing to happen with our Cucumber features. The features should
describe how the system behaves today, but they don’t need to document the history
of how it was built; that’s what a version control system is for!
We’ve seen teams whose features directory looks like this:
features/
story_38971_generate_new_report.feature
story_38986_run_report.feature
story_39004_log_in.feature
...
We strongly encourage you not to do this. You’ll end up with fragmented features that
just don’t work as documentation for your system. One user story might map to one
feature, but another user story might cause you to go and add or modify scenarios
in several existing features—if the story changes the way users have to authenticate,
for example. It’s unlikely that there will always be a one-to-one mapping from each
user story to each feature, so don’t try to force it. If you need to keep a story identifier
for a scenario, use a tag instead.
@slow @widgets @nightly
Scenario: Generate overnight report
Given I am logged in
And there is a report "Total widget sales history"
...
If you want to tag all the scenarios in a feature at once, just tag the Feature
element at the top, and all the scenarios will inherit the tag. You can still tag
individual scenarios as well.
@nightly @slow
Feature: Nightly Reports
@widgets
Scenario: Generate overnight widgets report
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• Chapter 5. Expressive Scenarios
...
@doofers
Scenario: Generate overnight doofers report
...
In the previous example, the scenario called Generate overnight widgets report will
have three tags: @nightly, @slow, and @widgets, whereas the scenario called Generate overnight doofers report will have the tags @nightly, @slow, and @doofers. You can
also tag Scenario Outline elements and even the individual Examples tables beneath
them.
There are three main reasons for tagging scenarios:
• Documentation: You simply want to use a tag to attach a label to certain
scenarios, for example to label them with an ID from a project management
tool.
• Filtering: Cucumber allows you to use tags as a filter to pick out specific
scenarios to run or report on. You can even have Cucumber fail your test
run if a certain tag appears too many times.
• Hooks: Run a block of Ruby code whenever a scenario with a particular
tag is about to start or has just finished.
We’ll cover hooks later in Tagged Hooks, on page 147, and we’ll explain how
to filter based on tags in Filtering with Tag Expressions, on page 193. In case
you can’t wait until then, here’s a quick example of how to run Cucumber,
selecting just scenarios with a certain tag:
$ cucumber --tags @javascript
That will select and run only the scenarios tagged with @javascript.
5.7
What We Just Learned
Congratulations, you’ve graduated from Gherkin school! Let’s look back over
what we’ve learned in this chapter.
• Readability should be your number-one goal when writing Gherkin features. Always try to sit together with a stakeholder when you write your
scenarios, or at the very least pass them over for feedback once you’ve
written them. Keep fine-tuning the language in your scenarios to make
them more readable.
• Use a Background to factor out repeated steps from a feature and to help
tell a story.
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What We Just Learned
• 83
• Repetitive scenarios can be collapsed into a Scenario Outline.
• Steps can be extended with multiline strings or data tables.
• You can organize features into subfolders, like chapters in a book.
• Tags allow you to mark up scenarios and features so you select particular
sets to run or report on.
Have you noticed that we’re going outside-in as we work through this part of
the book? We started with an overview, then looked at the most useful bits
of Gherkin, and then did the same for step definitions. Now that you’ve learned
about the more advanced features of Gherkin, you’re almost ready to dive
deep into step definition Ruby code. In the next part of the book, that’s exactly
what we’ll do, with a worked example that will give you a chance to practice
everything you’ve learned, and more. First, though, we’re going to take a step
back and examine some of the common problems you and your team might
encounter as you start to use Cucumber and what to do about them.
Try This
Review the scenarios that you’ve written for your system, and see whether
you can find an opportunity to use a Background, a Scenario Outline, or a data table.
Refactor the feature to make use of the new keyword and compare the new
version of the feature with the old one. Which one do you think is more
readable? Show it to someone else on your team; what do they think?
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CHAPTER 6
When Cucumbers Go Bad
When your team first starts to use Cucumber, it won’t be long before you
start to notice that you seem to be creating code with fewer bugs than you
did before. You might find yourself bravely refactoring in code that previously
you would have been too scared to touch. You’ll continue adding feature after
feature, inspired by the delight you felt on seeing your first passing scenario.
After a while, however, things can start to turn sour. Suddenly it dawns on
you that the tests take a really long time to run. Or perhaps you’ve started
to notice a couple of scenarios that seem to fail at random, usually just when
you’re up against a tight deadline. Perhaps the nontechnical stakeholders
have lost interest in the process, and only developers are reading the features
anymore. People might even start to ask this:
Is Cucumber holding us back?
The good news is, there are solutions to these problems. In our coaching and
consulting work, we’ve seen all kind of problems experienced by all kinds of
teams as they learn to use Cucumber. In this chapter, we’ll describe the most
common problems we’ve seen. We’ll help you understand their root causes,
and we’ll make suggestions for tackling them or, ideally, avoiding them in the
first place. There won’t be much code in this chapter, but you’ll find lots of
useful advice.
We’ll start where it hurts, by describing four different symptoms your team
might be experiencing. Then we’ll dig down into the underlying causes of
these, before finally looking at solutions. By the end of the chapter, you should
feel much more confident about how to help your team stay successful with
Cucumber in the long run.
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6.1
• Chapter 6. When Cucumbers Go Bad
Feeling the Pain
We’ve identified four main types of pain that your team might start to feel if
their Cucumber goes bad. Take a look and see whether you recognize any of
these:
Symptom
Problem
Some of our tests fail randomly.
Flickering scenarios
We keep breaking tests unintentionally.
Brittle features
Our features take too long to run.
Slow features
Our stakeholders don’t read our features.
Bored stakeholders
Let’s take a closer look at each of these symptoms.
Flickering Scenarios
When a scenario that was passing yesterday is failing today, with the same
source code running in the same environment, you have what we call a
flickering scenario. Here’s our definition of a flickering scenario:
Flickering scenario
A flickering scenario fails occasionally and at random. The same scenario,
run on the same codebase in the same environment, will mostly pass but
sometimes fail. These apparently uncontrollable failures cause the team
to lose confidence in their tests, in their code, and in themselves.
The worst thing about a flickering scenario is that as soon as you try to reproduce it so that you can fix it, it refuses to fail. Fixing a flickering scenario is
one of the hardest tasks you can take on, yet it’s also one of the most important. For a suite of automated tests to be useful, the team must have absolute
trust in it. When even just a single test is compromising that trust, it has a
corrosive effect on how everyone feels about the whole test suite.
To fix a flickering scenario, you have to study the code and try to understand
why it might be happening. This is a scientific process of making a hypothesis
about the cause of the failure, creating an experiment to prove or disprove
that hypothesis, and then running the experiment to see whether you were
right. You might need to go around this loop several times before you crack
the problem, and it might take several days to run an experiment, if the
flickering scenario fails only intermittently. If you run out of ideas, consider
simply deleting the test altogether rather than have it come back and fail on
you at a time of its own choosing.
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Flickering scenarios are normally caused by one of the following underlying
problems:
• Shared Environments, on page 100
• Leaky Scenarios, on page 97
• Race Conditions and Sleepy Steps, on page 99
Brittle Features
When you feel like you can hardly move in the test suite without making an
apparently unrelated test fail for no good reason, you have what we call brittle
features. Here’s our definition:
Brittle feature
A brittle feature is easy to break. When features are brittle, a necessary
change in one part of the test suite or main codebase causes apparently
unrelated scenarios to break.
When you encounter a brittle scenario, it’s usually when you’re in the middle
of doing something else. You’re interrupted by the unexpected failure and
waste time dashing over to fix the unexpected broken test. On a bad day, this
can happen several times before you emerge from the rabbit warren. Brittle
features are self-fulfilling: when developers perceive their tests to be brittle,
they tend to be less courageous about refactoring and cleaning up test code
and instead try to get in and out as quickly as they can, leaving the tests and
production codebase in an increasingly hard-to-maintain state.
Brittle features are normally caused by one of the following underlying
problems:
•
•
•
•
Fixture Data, on page 101
Duplication, on page 93
Leaky Scenarios, on page 97
Tester Apartheid, on page 101
Slow Features
Each time you add a new scenario to your test suite, you’re adding a few
seconds to the total test run time. For a successful application whose users
continue to demand new features, that test run time is only going to get
longer. A long test run creeps up on you: first five minutes seems like an
eternity to wait, then fifteen minutes seems bad, but you get used to going
to grab a coffee while it runs. Pretty soon, you come back from your coffee
and it still hasn’t finished, and fifteen minutes becomes twenty-five minutes.
Before you know it, your features are taking more than an hour or even longer.
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Once a new scenario is passing, the main reason to keep running it is for
feedback: you want that scenario to warn you if you somehow accidentally
break the functionality that it checks for. The value of that feedback diminishes as your test run starts taking longer and longer. When the build is slow,
developers don’t run all the tests before committing code and will rely on the
continuous integration server to give them feedback instead. If a few developers
do this at the same time, the chances of all of their changes integrating successfully are slim, and a broken build becomes the norm.
Long test runs also mean people are scared to refactor and do other general
maintenance on the Cucumber tests themselves. Refactoring the code in a
step definition that’s used in 340 scenarios is scary, because you’ll need to
run all 340 scenarios to tell you for certain whether your change broke
anything.
A slow feature run is normally caused by a combination of the following:
• Race Conditions and Sleepy Steps, on page 99
• Lots of Scenarios, on page 103
• Big Ball of Mud, on page 104
Bored Stakeholders
“Our stakeholders don’t read our features.” This is a common complaint from
teams that have tried Cucumber but failed to make it stick as anything other
than a tool for automating their test scripts. Yet many other teams attest to
the transformative effect Cucumber has had, helping development teams to
collaborate much more effectively with their business stakeholders. What
could be the difference between these two experiences?
The answer lies partly in starting with the right kind of collaborative relationship with those business stakeholders. If they think they’re too busy to help
you understand exactly what they want, then you have a deeper team problem
that Cucumber can’t help you solve. On the other hand, many teams who
start out with keen and interested stakeholders waste the opportunity Cucumber gives them to build that collaborative relationship. When features are
written by testers or developers working alone, they inevitably use technical
terms that make the stakeholders feel marginalized when they read them.
This becomes a vicious circle: as stakeholders lose interest, they spend less
time helping write the features in a language that makes sense to them. Before
you know it, the features have become nothing more than a testing tool.
This painful symptom is normally caused by a combination of the following
underlying problems:
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Running Cucumber Tests in Parallel
If you’re stuck with a slow set of features, a pragmatic option can be to run them in
parallel. The simplest approach to this is to partition your features using tags or
folders and then run each of those partitioned sets at the same time. Many continuous
integration tools like Jenkinsa allow you to delegate builds to slave machines so you
can ensure that each partitioned set of features gets its own dedicated environment.
Another approach is to use a tool like Testbotb or Hydrac to distribute your features
automatically across several slave machines.
Whatever approach you choose, you’ll definitely need a One-Click System Setup, on
page 102.
a.
b.
c.
•
•
•
•
•
http://jenkins-ci.org/
http://rubygems.org/gems/testbot
http://rubygems.org/gems/hydra
Incidental Details, on page 90
Imperative Steps, on page 91
Duplication, on page 93
Ubiquitous What?, on page 94
Siloed Features, on page 95
Once you’ve spotted any of these symptoms in your team, you need to know
what to do. It’s time to look at the underlying problems that are at work and
what you can do about them.
6.2
Working Together
Cucumber features are what Gojko Adzic4 calls living documentation. That
term neatly sums up the two main benefits of using Cucumber:
• Living: It tests the system automatically so you can work on it safely.
• Documentation: It facilitates good communication about the current or
planned behavior of the system.
When your team is struggling with Cucumber, the problems you’re having
will hit you in one of these two places. Either they’ll result in Cucumber scenarios that provide poor feedback for the developers or they’ll mean Cucumber
fails to help your team communicate. We’ll start by looking at what might be
holding you back from making the features work as a communication tool.
4.
Specification by Example [Adz11]
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Incidental Details
Consider the following scenario for an online email client:
Scenario: Check inbox
Given a User "Dave" with password "password"
And a User "Sue" with password "secret"
And an email to "Dave" from "Sue"
When I sign in as "Dave" with password "password"
Then I should see 1 email from "Sue" in my inbox
There is a lot of detail in this scenario: we have the username and password
of the main actor, Dave, and we also have the username and password of
another user, Sue. The usernames are quite useful, because they help tell
the story of the scenario, but the passwords are just noise: the passwords of
the users have nothing to do with what’s being tested and in fact are making
it harder to read. For example, Sue has a different password than Dave. As
you read the scenario, wondering whether this is relevant, you’re distracted
from the main point of the scenario: to check that Dave can see Sue’s email.
We call details like the passwords incidental details,5 which are details that
are mentioned in the scenario but that actually have no relevance to the
purpose of the scenario. This kind of irrelevant detail makes the scenario
harder to read, which in turn can cause your stakeholders to lose interest in
reading them. Let’s rewrite the scenario without the passwords:
Scenario: Check inbox
Given a User "Dave"
And a User "Sue"
And an email to "Dave" from "Sue"
When I sign in as "Dave"
Then I should see 1 email from "Sue" in my inbox
This is definitely an improvement, making it easier to read and understand
the essence of the scenario. Let’s try stripping away some more of the noise:
Scenario: Check inbox
Given I have received an email from "Sue"
When I sign in
Then I should see 1 email from "Sue" in my inbox
Now we have a simple three-step scenario that’s clear and concise. It’s also
more maintainable: if our product owner wants us to change the authentica-
5.
This term comes from the excellent paper “Writing Maintainable Acceptance Tests” by
Dale Emery: http://dhemery.com/pdf/writing_maintainable_automated_acceptance_tests.pdf.
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tion mechanism, we can just rewrite the underlying step definition code
without having to touch the features.
Avoiding Incidental Details
If you’re a programmer, you’re probably practiced at filtering out irrelevant
details as you read code each day. Bear that in mind when you write scenarios,
because you may not even notice these incidental details slipping in.
Try to avoid being guided by existing step definitions when you write your
scenarios and just write down exactly what you want to happen, in plain
English. In fact, try to avoid programmers or testers writing scenarios on their
own. Instead, get nontechnical stakeholders or analysts to write the first draft
of each scenario from a purely business-focused perspective or ideally in a
pair with a programmer to help them share their mental model. With a wellengineered support layer, you can confidently and quickly write new step
definitions to match the way the scenario has been expressed.
Imperative Steps
In computer programming, there are two contrasting styles for expressing
the instructions you give to a computer to make it do something for you.
These styles are called imperative programming and declarative programming.
Imperative programming means using a sequence of commands for the computer to perform in a particular order. Ruby is an example of an imperative
language: you write a program as a series of statements that Ruby runs one
at a time, in order. A declarative program tells the computer what it should
do without prescribing precisely how to do it. CSS is an example of a declarative language: you tell the computer what you want the various elements on
a web page to look like, and you leave it to take care of the rest.
Gherkin is, of course, an imperative language. Cucumber executes each step
in a scenario, one at a time, in the sequence you’ve written them in. However,
that doesn’t mean those steps need to be read like the instructions for assembling a piece of flat-pack furniture. Let’s take a look at a typical example
written in an imperative style:
Scenario: Redirect user to originally requested page after logging in
Given a User "dave" exists with password "secret"
And I am not logged in
When I navigate to the home page
Then I am redirected to the login form
When I fill in "Username" with "dave"
And I fill in "Password" with "secret"
And I press "Login"
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Then I should be on the home page
What’s good about this scenario? Well, it uses very generic step definitions,
like /^I fill in "(.*)" with "(.*)"$/", which means you can write lots of scenarios like
this without having to create much step definition code. You could also
probably just about make the argument that it acts as a guide to what the
user interface will look like, since it names the fields and buttons that will
be used in the login form.
However, when a team uses such an imperative style for their step definitions,
it won’t be long before they’re experiencing the pain of brittle tests and bored
stakeholders. Scenarios written in this style are not only noisy, long, and
boring to read, but they’re easy to break: if the user-experience people decided
to change the wording on the submit button from Login to Log in, the scenario
will fail, for no good reason at all.
Worst of all, scenarios that use generic step definitions like this are failing to
create their own domain language. The language of this scenario, using words
and phrases like fill in and press, is expressed in the domain of user interface
widgets, a generic and relatively low-level domain.
Use a Declarative Style Instead
Let’s raise the level of abstraction in this scenario and rewrite it using a more
declarative style:
Scenario: Redirect user to originally requested page after logging in
Given I am an unauthenticated User
When I attempt to view some restricted content
Then I am shown a login form
When I authenticate with valid credentials
Then I should be shown the restricted content
The beauty of this style is that it is not coupled to any specific implementation
of the user interface. This same scenario could apply to a thick-client or mobile
application. The words it uses aren’t technical and are instead written in a
language (unauthenticated, restricted, credentials) that any stakeholder interested in security should be able to clearly understand. It’s by expressing every
scenario at this level of abstraction that you discover your team’s ubiquitous
language.
It’s true that using declarative style will mean you have to write more step
definitions, but you can keep the code in those step definitions short and
easy to maintain by pushing the actual work off into helper methods in your
support code. We’ll show you how to do this in Chapter 8, Support Code, on
page 133.
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The Spectrum from Imperative to Declarative
In Gherkin features, there isn’t a clear line between imperative and declarative styles.
Instead, there’s a spectrum, and the right place on that spectrum for each step in
each scenario depends on lots of things: the area of the system you’re describing, the
kind of application you’re building, the domain expertise of the programmers, and
the level of trust that the nontechnical stakeholders have in the programmers. If your
stakeholders want to see a lot of detail in the features, it may indicate that you need
to work on that trust, but it may just mean you’re working on the kind of system that
needs to be specified in lots of detail.
You can take declarative style too far, removing so much of the detail from a scenario
that it loses its ability to tell a story:
Scenario: The whole system
Given the system exists
When I use it
Then it should work, perfectly
This scenario is ridiculous, of course, but it illustrates what can happen when you
raise the level of abstraction so high that your scenario doesn’t tell the reader anything
interesting at all. A team that used this scenario would need an incredibly high level
of trust in their programmers. We’re encouraging you to push your team toward the
more abstract, declarative end of the spectrum, but as always, the most important
thing is to work with your nontechnical stakeholders to get the level right for them.
Duplication
All good computer programmers understand how destructive duplication is
to the maintainability of their code. Yet we often see duplication rife in teams’
Cucumber features. Duplication obviously makes your scenarios brittle, but
it also makes them boring.
Gherkin has the Background and Scenario Outline keywords you can use to reduce
duplication, as we showed you in Chapter 5, Expressive Scenarios, on page
61, but stay vigilant for where the duplication is a sign that your steps are
written at too low a level of abstraction. If you have steps that are too imperative, any amount of moving them into Backgrounds or Scenario Outlines won’t help
you. Work with nontechnical members of your team to get their feedback
about the kind of duplication they can accept and the kinds that make their
eyes glaze over.
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Let Your Examples Flow
by: Dan North
The DRY principle6 (Don’t Repeat Yourself) says that the definition of any concept should appear
once and only once in your code. This is an admirable aim in that if you have to change the
behavior of the system, you want to be able to change it in one place and be confident that your
change will apply consistently across the codebase. If there are multiple definitions of that
behavior scattered around the code, the chances are that not only will you not catch them all
but someone before you didn’t catch them all and the multiple definitions are already inconsistent,
and who wants that?
However, when you are using examples to drive your code, there is another principle in play
that I believe trumps the DRY principle: the examples should tell a good story. They are the documentation narrative that will guide future programmers (including you when you come back to
change this code in three months time and you’ve forgotten what it does). In this case, clarity
of intent is found in the quality of the narrative, not necessarily in minimizing duplication.
Some years ago I had my first experience of pair programming with Martin Fowler. That is, I had
done quite a bit of pair programming, just not with Martin before. We were looking at some
Ruby code I had written test-first, and Martin asked to see the tests "to find out what the code
does." Then he did a rather odd thing. He started moving the tests around. I had a few helper
classes and utility methods in the source file, neatly at the end out of the way. He moved them
up and dropped them inline just ahead of the first test that used them.
Madness! I thought—now the supporting code is all over the place! It really offended my sense
of tidiness. But then I saw a pattern beginning to emerge: the test code was starting to read like
a story. He would introduce these little methods and classes just before their one walk-on line
in the narrative. It was quite an eye-opener for me. The test code flowed and unfolded the story
of the class under test.
The a-ha! moment for me was when I imagined reading a book where the plot and characters
had been DRYed out. Everything would be in footnotes or appendixes. All the character descriptions, plot elements, subtexts, and so on, would be carefully extracted into fully cross-referenced
paragraphs. That is great if you are reading an encyclopedia but not so appropriate if you want
to get into the flow and find out what happens. You would be forever flicking back and forth in
the book, and you would very quickly forget where you even were in the story. In the words of
the old joke, dictionaries have lousy plots, but at least they explain all the words as they go.
Some people refer to this as the DAMP principle: Descriptive and Meaningful Phrases. When
you’re writing examples, readability is paramount, and DAMP trumps DRY.
Ubiquitous What?
The ubiquitous language your team uses will be driven by the domain you’re
working in. If you’re building a system for live-music fans, your ubiquitous
language will include words like concert, performance, artist, and venue. If
6.
The Pragmatic Programmer: From Journeyman to Master [HT00]
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you’re building a catalog of TV shows, you’ll have words like broadcaster,
genre, duration, and transmission date in your ubiquitous language.
The point is for everyone on the team to use the same words, everywhere. It’s
not OK to have a database table called tbl_Performer if the rows in that table
represent things that most of the team refers to as artists. Wherever you see
schism like this, stop, decide which is the right word to use, make the appropriate correction, and then stick with it.
We talk about developing a ubiquitous language because it’s an ongoing
process. That development takes work. It takes effort to really listen to one
another and agree on the words you’ll use, and it takes discipline to stick to
those commitments.
The rewards are great. Teams that use a ubiquitous language make fewer
mistakes and enjoy their work more because they can communicate effectively
about the work. When a team doesn’t appreciate the value of a ubiquitous
language, they’ll be careless with the wording of their scenarios, missing a
valuable opportunity to build strong bridges between the technical and
business-focused sides of the team. When you try to correct people or clarify
terminology, you might end up feeling like you’re just being picky.
Take time to explain the concept of a ubiquitous language to your team and
what its benefits are. Once everyone understands why it’s important, you’ll
find they’re much more willing to help make the effort to discuss and decide
on the right words to use.
Used correctly, Cucumber helps a team to develop their ubiquitous language.
When programmers and businesspeople work together to write scenarios,
you’ll find all kinds of arguments breaking out about how precisely to word
things. Great! Each of those disagreements has exposed a potential misunderstanding between the two groups, in other words, a bug magnet. For a new
team, these sessions can be hard at first, but as the language develops, they
get easier and easier. Three Amigos, on page 96 is a good way to structure
these meetings.
Siloed Features
Cucumber can feel like a very technical tool. It’s run from the command line,
and the feature files are designed to be checked into source control along
with the code that they test. Yet it’s supposed to help the business stakeholders on your team feel more in control of the development process. When testers
and developers tuck their features away in source control, the rest of the team
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Three Amigos
The best Gherkin scenarios are created when the three amigos come together,
bringing three very different perspectives:
• The first amigo is a tester, who thinks about how to break things. The tester will
typically come up with lots of scenarios, sometimes covering obscure edge cases
and sometimes covering very important ones that no one else had thought of.
• The second amigo is a programmer, who thinks about how to make things. The
programmer will typically add steps to scenarios, as he asks clarifying questions
about what exactly should happen.
• The third amigo is the product owner, who cares about scope. When the tester
thinks of scenarios that hit edge cases the product owner doesn’t care about,
she can tell the team to drop that scenario out of scope altogether, or the group
can decide to test it with unit tests only. When the programmer explains that
implementing a particular scenario will be complicated, the product owner has
the authority to help decide on alternatives or to drop it altogether.
Many teams practicing BDD have found the three amigos make a great partnership
for thrashing out Gherkin scenarios that the whole team believes in. You don’t have
to stop at three amigos, though: invite your team’s user experience specialists or operations staff, for example, if the feature being discussed will affect them.
can feel as though their documentation had been locked away in a cupboard
to which they don’t have the keys.
Your features act as a design tool for specifying new features, but they also
act as a great reference document for what the system already does today.
For a system of any significant size, no one person will remember exactly
what it will do in every situation, so when you get a bug report from a user
or are considering adding new functionality to some part of the system, you
want this reference right at your side.
Cucumber itself has only limited support for sharing features in a way that’s
accessible for nontechnical audiences, but there are plenty of plug-ins and
tools springing up around it that do. For example, if you use GitHub for source
control, the pages for your project will have syntax-highlighted features that
people can even comment on.
Relish7 is a service that was created by members of the Cucumber and RSpec
teams to provide an easy way to publish Cucumber features as documentation.
7.
http://relishapp.com
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The RSpec project now uses its Relish documentation as its home page, and
your team can use it too.
You can achieve at least half of the benefit of Cucumber just by having the
discipline to sit down with your business stakeholders and write scenarios
collaboratively. The conversations sparked by that process will uncover so
many potential bugs or schedule overruns that you’ll already have made a
huge win, even if you choose to never automate your features.
Assuming you do want to automate them, however, read on to find out how
to do it well.
6.3
Caring for Your Tests
The benefit of automating your features is that you’ll be able to trust them
as living documentation in the long run, because you’ll be checking each
scenario against the production code to make sure it’s still valid. For the
programmers working on the code, there’s another benefit too: those tests
act as a safety net when they’re working on the system, alerting them to any
mistakes they make that break existing behavior.
So, your features work as a feedback mechanism to the whole team about
the behavior of the system and to the programmers about whether they’ve
broken anything. For these feedback loops to be useful, the tests need to be
fast and they need to be reliable. Let’s start by looking at problems that affect
the reliability of your tests.
Leaky Scenarios
Cucumber scenarios are basically state-transition tests: you put the system
into a Given state A, you perform action X (When), and Then you check that it
has moved into expected state B. So, each scenario needs the system to be
in a certain state before it begins, and yet each scenario also leaves the system
in a new, dirty state when it’s finished.
When the state of the system is not reset between tests, we say that they allow
state to leak between them. This is a major cause of brittle tests.
When one scenario depends upon state left behind by another earlier scenario
in order for it to pass, you’ve created a dependency between the two scenarios.
When you have a chain of several scenarios depending on each other like
this, it’s only a matter of time before you end up with a train wreck.
If that first scenario, the one that happens to leave the system in just the
right state for the next one to pick it up, is ever changed, the next scenario
will suddenly start to fail. Even if you don’t change that earlier scenario, what
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Test Data Builders
If you’re using Ruby, you’re probably familiar with the FactoryGirla gem. FactoryGirl
is an excellent implementation of the Test Data Builderb pattern. For the uninitiated,
here’s a quick summary of its benefits.
Suppose you’re testing a payroll system and you need to create a PayCheck record as
part of a scenario. The way your domain model is structured, a PayCheck needs an
Employee, and the Employee in turn needs an Address. Each of them also has a few
mandatory fields. Instead of having to create all these objects individually in your
step definition code or having a big fat set of fixture data, you can simply say this:
Given /^I have been paid$/ do
Factory :pay_check
end
Once you’ve configured FactoryGirl with the structure of your data model (see the
FactoryGirl documentation for details on how this is done), all you need to do is ask
her for a PayCheck, and she’ll create not only the PayCheck record but all the dependent
objects as well, setting the mandatory fields with reasonable default values. If you
care about a field having a specific value, you can tell her to override the default:
Given /^I have been paid 50 dollars$/ do
Factory :pay_check, :amount => 50
end
When it’s this easy to create data, you no longer need to carry around the baggage
of big fixture data sets. There’s a small amount of up-front investment in creating
these builders, of course, but it quickly pays off in reliable, readable scenarios and
step definition code. If your team isn’t using Ruby, they could still point ActiveRecord
and FactoryGirl at their database with minimal effort. Otherwise, look for similar
tools for your language.
a.
b.
http://rubygems.org/gems/factory_girl
http://www.natpryce.com/articles/000714.html
happens if you want to run only the second scenario on its own? Without the
state leaked out by the earlier scenario, it will fail.
The opposite of this, independent scenarios, ensures they put the system into
a clean state and then add their own data on top of it. This makes them able
to stand on their own, rather than being coupled to the data left behind by
other tests or shared fixture data. Investing in building up a good reliable
library of Test Data Builders, on page 98 makes this much easier to achieve.
We can’t stress enough how fundamental independent scenarios are to successful automated testing. Apart from the added reliability of scenarios that
independently set up their own data, they’re also clearer to read and debug.
When you can see precisely what data is used by a scenario just by reading
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Matt says:
Fixture Is an Overloaded Term
The word fixture has at least three meanings in the domain of automated testing,
which can cause confusion. We’ve used the term fixture data in this chapter to mean
data that’s used to set up the context for a scenario or test case. This is the common
meaning of the term as used in various xUnit testing toolsa and by the Ruby on Rails
framework.
There is a long tradition (coming from the hardware world, where test fixtures originated) of calling the link between the test system and the system under test a fixture.
This is the “glue code” role that we’ve referred to in this book as automation code. The
FIT testing frameworkb uses this meaning of the term.
Some unit testing tools (such as NUnit) have further confused the issue by referring
to the test case class itself as a fixture. So much for a ubiquitous language!
a.
b.
xUnit Test Patterns [Mes07]
http://fit.c2.com/
it, rather than having to root around in a fixture data script or, worse, in the
database itself, you’ll be able to understand and diagnose a failure much
more easily.
Race Conditions and Sleepy Steps
If you write end-to-end integration tests for a reasonably complex system,
you’ll eventually encounter this problem. Race conditions occur when two or
more parts of the system are running in parallel, but success depends on a
particular one of them finishing first. In the case of a Cucumber test, your
When step might cause the system to start some work that it runs in the
background, such as generating a PDF or updating a search index. If this
background task happens to finish before Cucumber runs your Then step, the
scenario will pass. If Cucumber wins the race and the Then step executes before
the background task is finished, the scenario will fail.
When it’s a close race, you’ll have a flickering scenario, where the scenario
will pass and fail intermittently. If there’s a clear winner, a race condition can
go unnoticed for a long time, until a new change to the system evens up the
stakes, and the scenario starts to fail at random.
A crude solution to this problem is to introduce a fixed-length pause or sleep
into the scenario to give the system time to finish processing the background
task. Although this is definitely a useful technique in the very short term to
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diagnose a race condition, you should resist the temptation to leave a sleep
in your tests once you understand the cause of the problem. Introducing
sleepy steps won’t solve the flickering problem but just make it less likely to
happen. In the meantime, you’ve added a few extra seconds to your total test
run time, swapping one set of problems for another.
If we really had to choose, we’d choose slow, reliable tests over faster unreliable
ones, but there’s no need to make this compromise. When testers and programmers pair up to automate scenarios, they can craft tests that are built
with knowledge of how the system works. This means they can make use of
cues from the system to let the tests know when it’s safe to proceed, so instead
of using crude fixed-length sleeps, the tests can proceed as quickly as possible.
For an example of working with asynchronous code and further detail, see
Chapter 9, Dealing with Message Queues and Asynchronous Components, on
page 157.
Shared Environments
This is a problem that we’ve often found in teams that are transitioning from
a manual acceptance testing regime to using automated acceptance tests.
Traditionally, the manual testers on the team would have a special environment, often called system test, where a recent build of the system would be
deployed. They’d run their manual tests in that environment, reporting bugs
back to the development team. If more than one team member needed to run
tests in that same environment, they’d communicate between each other to
make sure they didn’t tread on one another’s toes.
If it’s even slightly awkward to install the system in a new environment, the
likelihood is that when the team starts to automate their tests, they’ll follow
the path of least resistance and point their test scripts at this existing system
test environment. Now the environment is shared between not only the human
members of the team but the test scripts too. Suppose a developer gets a bug
report and wants to reproduce it for himself. He logs in to the system test
environment and clicks a few buttons, but he doesn’t realize the automated
tests are running at the same time. As part of the steps to reproduce the bug,
the developer unwittingly deletes a database record that the automated test
relied on, and the automated test fails. This kind of situation is a classic
cause of flickering scenarios.
The shared use of a single environment can also contribute to unreliable tests
by causing heavy and inconsistent load on in-demand resources like
databases. When the shared database is under excessive load, normally reliable tests will time out and fail.
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Caring for Your Tests
• 101
To deal with this problem, it needs to be so easy to spin up the system in a
new environment that you can do it for fun. You need a One-Click System
Setup, on page 102.
Tester Apartheid
Testers are too often unfairly regarded as second-class citizens on a software
team. As we’ll explain in Chapter 8, Support Code, on page 133, developing a
healthy suite of Cucumber features requires not only testing skill but programming skill too. When testers are left alone to build their own Cucumber tests,
they may lack the software engineering skill to keep their step definition and
support code well organized. Before you know it, the tests are a brittle muddle
that people are scared to change.
Combat this problem by encouraging programmers and testers to work together when writing step definition and support code. The programmers can show
the tester how to keep the code organized and factor out reusable components
or libraries that other teams can use. This is precisely how libraries like
Capybara (see Chapter 15, Using Capybara to Test Ajax Web Applications, on
page 245) were created, when a programmer extracted reusable code from their
team’s step definitions. By pairing with testers like this, programmers also
develop a better understanding of what it takes to make their code testable.
When Cucumber is being used to good effect on a team, a tester should be
able to delegate the work of running basic checks to Cucumber. This frees
them up to do the much more interesting, creative work of exploratory testing,
as explained in Agile Testing: A Practical Guide for Testers and Agile Teams
[CG08].
Fixture Data
When manually testing a system, it’s useful to populate it with realistic data
so that you can wander around the system just like you would in the live
application. When your team transitions from manual to automated tests,
you can often be tempted to just port over a subset of production data so that
the automated tests have a functioning system to work with straightaway.
The alternative, having each test set up its own data, might seem like it’s just
too hard. In a legacy system—especially one where the design has evolved
organically—where creating the single object actually needed for the test
you’re working on means you need to create a huge tree of other dependent
objects, you’ll feel like the easiest option is just to create this tree once in the
fixture data and then share it with all the other tests.
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One-Click System Setup
To avoid flickering scenarios that result from using shared environments, the team
needs a setup script that will create a new instance of the system from scratch, at
the click of a button.
If the system has a database, the database generated by the script should contain
the latest schema, as well as any stored procedures, views, functions, and so on. It
should contain just the very minimum baseline data necessary for the system to be
able to function, such as configuration data. Any more should be left for the independent scenarios to create for themselves.
If there are message queues, or memcache daemons, the setup script should start
them too, with the minimal configuration that you’d expect to be there on the running
system.
Even if your team is not using Ruby for their production code, they could experiment
with using Ruby’s ActiveRecorda gem for managing database schemas and migration
scripts. ActiveRecord turns this kind of chore into a breeze.
a.
http://rubygems.org/gems/activerecord
This approach has a couple of significant problems. A set of fixture data, even
if it starts out relatively lean, will only tend to grow in size over time. As more
and more scenarios come to rely on the data, each needing their own specific
little tweaks, the size and complexity of the fixture data grows and grows.
You’ll start to feel the pain of brittle features when you make a change to the
data for one scenario, but that change causes other scenarios to fail. Because
you have so many different scenarios depending on the fixture data, you’ll
tend to plaster on more data because it’s safer than changing the existing
data. When a scenario does fail, it’s hard to know which of the masses of
data in the system could be relevant to the failure, making diagnosis much
more difficult.
When you have a large set of fixture data, it can be slow to set it up between
each test. This puts pressure on you to write leaky scenarios that don’t reset
the state of the system between each scenario, because it’s quicker not to do
so. We’ve already explained where this can lead.
We consider fixture data to be an antipattern. We much prefer using Test
Data Builders, on page 98 like FactoryGirl13 where the relevant data is created
within the test itself, rather than being buried away in a big tangled set of
fixture data.
13. https://github.com/thoughtbot/factory_girl
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Caring for Your Tests
• 103
Nightly Build
When you have Slow Features, on page 87, caused by Lots of Scenarios, on page 103,
it’s worth considering splitting your build in two. Use tags to annotate the scenarios
that should be run on every check-in, and demote the rest to a nightly build.
Use of this pattern depends on your team’s appetite for risk, as well as their tendency
to make mistakes. The scenarios that should be demoted to a nightly build are the
ones that rarely, if ever, fail. They’re the scenarios for functionality that hasn’t changed
for months, and they cover stable code that isn’t being worked on. They’re the scenarios that if you had to, you’d be prepared to delete altogether.
There’s a maintenance overhead in keeping the tags for the check-in build on the
right scenarios. Over time, some of those scenarios will stabilize and should be
demoted to the nightly build, to be replaced by newer scenarios.
Although a nightly build can be a good way to get you out of a hole, usually the right
long-term solution is to break up your Big Ball of Mud, on page 104.
Lots of Scenarios
It might seem like stating the obvious, but having a lot of scenarios is by far
the easiest way to give yourself a slow overall feature run. We’re not trying to
suggest you give up on BDD and go back to cowboy coding, but we do suggest
you treat a slow feature run as a red flag. Having lots of tests has other disadvantages than just waiting a long time for feedback. It’s hard to keep a
large set of features organized, making them awkward for readers to navigate
around. Maintenance is also harder on the underlying step definitions and
support code.
We find that teams that have a single humongous build also tend to have an
architecture that could best be described as a big ball of mud. Because all of
the behavior in the system is implemented in one place, all the tests have to
live in one place, too, and have to all be run together as one big lump. This
is a classic ailment of long-lived Ruby on Rails applications, which tend to
grow organically without obvious interfaces between their subsystems.
We’ll talk more about what to do with big balls of mud in the next section.
It’s really important to face up to this problem and tackle it once you realize
it’s happening, but it isn’t a problem you’ll be able to solve overnight.
In the meantime, you can keep your features organized using subfolders and
tags (see Chapter 5, Expressive Scenarios, on page 61). Tagging is especially
helpful, because you can use tags to partition your tests. You can choose to
run partitioned sets of tests in parallel or even demote some of them to run
in a Nightly Build, on page 103.
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It’s also worth thinking about whether some of the behavior you’ve specified
in Cucumber scenarios could be pushed down and expressed in fast unit
tests instead. Teams that enthusiastically embrace Cucumber sometimes
forget to write unit tests as well and rely too much on slow integration tests
for feedback. Try to think of your Cucumber scenarios as broad brush strokes
that communicate the general behavior of the code to the business, but still
try to get as good a coverage as you can from fast unit tests. Help make this
happen by having testers and programmers work in pairs when implementing
Cucumber scenarios. This pair can make good decisions about whether a
piece of behavior necessarily needs to be implemented in a slow end-to-end
Cucumber scenario and drive out the behavior using a fast unit test instead.
Big Ball of Mud
The Big Ball of Mud14 is an ironic name given to the type of software design
you see when nobody has really made much effort to actually do any software
design. In other words, it’s a big, tangled mess.
We’ve explained where a big ball of mud will manifest itself as problems in
your Cucumber tests: slow features, fixture data, and shared environments
are all examples of the trouble it can cause. Look out for these signals and
be brave about making changes to your system’s design to make it easier to
test.
We suggest Alistair Cockburn’s ports and adapters architecture15 as a way of
designing your system to be testable. Michael Feathers’ Working Effectively
with Legacy Code [Fea04] gives many practical examples of breaking up large
systems that weren’t designed to be tested.
Hold regular sessions with your team to talk about your architecture: what
you like, what you don’t like, and where you’d like to take it. It’s easy to get
carried away with ambitious ideas that evaporate into thin air soon after you
get back to your desks, so make sure you try to leave these sessions with
realistic, practical steps that will move you in the right direction.
That covers the most common problems you’re likely to hit as you adopt
Cucumber into your team. However, it’s one thing to understand these
problems, but it’s quite another to get the time to do anything about them.
Next we’ll talk about an important technique for making that time.
14. http://www.laputan.org/mud/
15. http://alistair.cockburn.us/Hexagonal+architecture
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Stop the Line and Defect Prevention
6.4
• 105
Stop the Line and Defect Prevention
Of all the activities that your team does, which do you think is the most
important? Writing code for new features? Fixing bugs found in testing? Fixing
bugs found in production? Speeding up your features?
Sadly, test maintenance does not come near the top of most software teams’
list of priorities. If the elevators are broken in your office building, you can
be sure that someone will be on the phone to the facilities team straightaway.
When your tests are slow or brittle, the problem is invisible to everyone but
the programmers and testers who rely on them. If you do test maintenance
at all, you generally do it when things have gotten so bad that you can’t stand
it any longer, or you simply can’t get a release out because the tests are so
broken. There just always seems to be something more important to do.
Team members who think in this way about their tests have got it all wrong.
The automated tests are the heartbeat of the team that relies on them, and
they need meticulous care and attention to keep them healthy.
Stop the Line at Toyota
In Toyota’s manufacturing plants, every shop-floor worker has the authority and the responsibility to stop an entire production line whenever a problem arises. The problem is then given
immediate and focused attention by experienced staff, and the line is restarted only once the
problem has been resolved. Once the line has restarted, a team is tasked with performing a rootcause analysis on the problem to understand why it happened so that the source of the problem
can be resolved.
When Taiichi Ohno16 first introduced this idea, his managers thought he was crazy. At the time,
it was taken for granted within the manufacturing industry that the most important thing you
could do was keep your assembly lines running, day and night if necessary.
When Ohno first told his managers to implement this new system, some of them listened and
some of them didn’t. At first, the managers who had implemented the policy saw their productivity drop. Stopping to deal with each problem immediately was slowing them down, and when
they compared their output numbers with the managers who had ignored their boss, it looked
like the boss had got it wrong.
Gradually, however, those managers who allowed their lines to stop and deal with every problem
started to see their lines stopping less frequently. Because each problem was being dealt with
using defect prevention, those lines had been investing in continuously improving the quality
of the machines and processes that ran the line. That investment started to pay off, and their
lines started to get faster and faster. Soon their output was much greater than that of the lines
controlled by the managers who had ignored their apparently crazy boss. Their production lines
were still clunking along at the same old rate, suffering the same old problems.
16. Toyota Production System - Beyond Large Scale Production [Ohn88]
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Defect Prevention
Toyota’s counterintuitive but hugely successful policy of stopping the line
works because it’s part of a wider process, known as defect prevention, that
focuses on continuously improving the manufacturing system. Without this
wider process, stop the line itself would have very little effect. There are four
steps to this process:
1.
2.
3.
4.
Detect the abnormality.
Stop what you’re doing.
Fix or correct the immediate problem.
Investigate the root cause and install a countermeasure.
This fourth step is crucial because it seizes the opportunity offered by the
problem at hand to understand something more fundamental about your
process. It also means that fixing things becomes a habit, rather than something you put off to do someday later when you’re not in such a hurry.
For example, suppose the build has broken with a failing test. It turns out
that the guy who pushed the commit with the failing test didn’t run all the
tests before he pushed. Why not? Well, it turns out that he thinks the tests
take too long to run, so he ran just what he thought were the ones covering
the change he made and then crossed his fingers and pushed his commit
anyway. So, the underlying cause is that the features are slow. Now that we
understand the root cause, we can work to fix it.
Some teams keep a log of build failures, recording the root cause each time.
When they have sufficient evidence that a particular root cause is worth
tackling, they can put some concentrated effort into tackling it properly.
Imagine your team as a production line, cranking out valuable features for
your users. If you spot a problem that’s slowing the production line down,
stop the line and fix the problem for good. Implementing stop the line means
you’ve decided to make a fast, high-quality, reliable test run your whole team’s
top priority, second only to dealing with production issues that are affecting
your customers. When there’s a problem with the tests—whether that’s an
urgent problem like a failing test or a nagging annoyance like a flickering
scenario—put your best people on it, and fix it forever.
6.5
What We Just Learned
Cucumber features are a valuable asset to your company. We’ve seen teams
that have ripped out and rewritten big parts of their systems, safe in the
knowledge that they had a set of accurate, executable specifications to ensure
the new solution worked just as well as the original. To those teams, the
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What We Just Learned
• 107
features were more valuable than the production code itself. If you’re going
to invest in writing Cucumber features, you need to protect that investment
by caring for them so that they’re as useful as possible to the whole team.
Don’t settle for features that are slow, that fail intermittently, or that are read
by only half the team: iron out problems as they happen, and use each
problem as a reason to make the tests even better than they were before.
Cucumber might just seem like a testing tool, but at its heart it’s really a
collaboration tool. If you make a genuine effort to write features that work as
documentation for the nontechnical stakeholders on your team, you’ll find
you are forced to talk with them about details that you might never have
otherwise made the time to talk about. Those conversations reveal insights
about their understanding of the problem, insights that will help you build
a much better solution than you would have otherwise. This is Cucumber’s
big secret: the tests and documentation are just a happy side effect; the real
value lies in the knowledge you discover during those conversations.
Try This
Here are some exercises for you to try for yourself.
Defect Prevention on Your Team
Think of three things that are slowing down your team’s production line. What
is the root cause of each of them? What could you do to change them for the
better?
Incidental Details Practice
Here is a scenario, written in a hideously imperative style, riddled with incidental details:
Scenario: Create an invoice
Given I am a signed in user with role: admin
And a client "Test Client" exists with name: "Test Client"
And a project "Test Project" exists with:
| name
| "Test Project"
|
| client | client "Test Client" |
And an issue "Test Issue" exists with:
| project | project "Test Project" |
| name
| "Test Issue"
|
And a work_unit "Test Work Unit" exists with:
| issue
| issue "Test Issue" |
| completed_on | "2011-08-24"
|
| hours
| "7.5"
|
And I am on the admin invoices page
Then I should see "Test Client"
And I follow "Test Client"
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And I fill in "invoice_id" with "abc"
And I press "Submit"
Then I am on the admin invoices page
And I should not see "Test Client"
Start by just trying to work out what’s going on: what do you think this system
does? What is the purpose of the scenario? What behavior is it trying to test?
Notice how the incidental details are like overgrown weeds, getting in the way
of you figuring out what the test is actually trying to do.
Now that you understand the essence of the scenario, rewrite it in your own
words. You should need much fewer steps, but you might want to consider
using more than one scenario.
Now that you’ve rewritten the scenario in a more declarative style, can you
spot the crucial Then step that was missing from the original scenario?
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Part II
A Worked Example
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CHAPTER 7
Step Definitions: On the Inside
It’s time to pull together everything that you’ve learned in the first part of the
book and use it in practice. There are a few advanced concepts left about
Cucumber that we want to explain to you, and they’ll be much easier to
demonstrate with an example. A lot of what we’ll do in this part of the book
will blur the line between testing and development. If you’re more of a tester
than a developer, don’t let that worry you: the Ruby code we’ll build is just
about as simple as it gets. By following along, you’ll get a good sense of how
we like to work, as well as pick up some new knowledge about working with
Cucumber.
At the end of Section 4.5, Returning Results, on page 52, we’d just started
work on a greenfield project to build the software for an ATM. We had a single
scenario for the most important behavior of the system: letting someone walk
up to the machine and withdraw cash.
Download step_definitions_inside/01/features/cash_withdrawal.feature
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I request $20
Then $20 should be dispensed
Now we’re going to pick up this scenario and work outside-in, designing the
system as we go, just as we would on a real project. In this chapter, we’ll get
the scenario to pass by driving out a simple domain model for our ATM. Then,
in the next chapter, we’ll get a nasty surprise when we discover that there’s
a missing step in our scenario. Finally, we’ll demonstrate the benefits of wellengineered test code by introducing a user interface around the domain
model.
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By the end of this chapter, you’ll have learned about Cucumber’s World and
how you can use it to contain state that’s shared between step definitions.
We’ll write some custom helper methods that will introduce a layer of decoupling between our step definitions and the application we’re building. We’ll
show you how to use transforms to reduce duplication in your step definitions
and make their regular expressions more readable. Finally, we’ll show you
how we like to organize the files in our projects so that they’re easy to work
with and maintain.
7.1
Sketching Out the Domain Model
The heart of any object-oriented program is the domain model. When we start
to build a new system, we like to work directly with the domain model. This
allows us to iterate and learn quickly about the problem we’re working on
without getting distracted by user interface gizmos. Once we have a domain
model that really reflects our understanding of the system, it’s easy to wrap
it in a pretty skin.
We’re going to let Cucumber drive our work, building the domain model
classes directly in the step definitions. As usual, we start by running cucumber
on our scenario to remind us what to do next:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
uninitialized constant Account (NameError)
./features/step_definitions/steps.rb:2
features/cash_withdrawal.feature:3
When I request $20
Then $20 should be dispensed
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
3 steps (1 failed, 2 skipped)
0m0.002s
When we last worked on this scenario, we’d just reached the point where we
had written the regular expressions for each of our step definitions and
started to implement the first one. Here’s how our steps file looks:
Download step_definitions_inside/01/features/step_definitions/steps.rb
Given /^I have deposited \$(\d+) in my account$/ do |amount|
Account.new(amount.to_i)
end
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Sketching Out the Domain Model
• 113
When /^I request \$(\d+)$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
Then /^\$(\d+) should be dispensed$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
In that first step definition, we’ve sketched out a call to an imaginary class
called Account. Ruby has given us an error that tells us that the next thing we
need to do is define the Account class. Let’s go ahead and do that:
Download step_definitions_inside/02/features/step_definitions/steps.rb
class Account
def initialize(amount)
end
end
Given /^I have deposited \$(\d+) in my account$/ do |amount|
Account.new(amount.to_i)
end
Notice that we’re defining the class right here in our steps file. Don’t worry—
it’s not going to stay here forever, but it’s most convenient for us to create it
right here where we’re working. Once we have a clear idea of how we’re going
to work with the class, then we can refactor and move it to a more permanent
home. We’re also converting the amount captured from the Gherkin step as
a string into a number before we pass it into the domain model.
Let’s run cucumber again and see what it thinks of that:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I request $20
TODO (Cucumber::Pending)
./features/step_definitions/steps.rb:13
features/cash_withdrawal.feature:4
Then $20 should be dispensed
1 scenario (1 pending)
3 steps (1 skipped, 1 pending, 1 passed)
0m0.002s
Well, that was easy! Perhaps...too easy? Let’s review the code in our step
definition and see what we think. There are a couple of things we’re not
happy about:
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• There’s some inconsistent language creeping in; the step talks about
depositing funds into the account, but the code passes the funds to the
Account class’s constructor.
• The step is lying to us! It says Given I have deposited $100 in my account, and it’s
passed. Yet we know from our implementation that nothing has been
deposited anywhere.
• Having to convert the amount to an integer is messy. If we have a variable
called amount, we should expect it to already be a number of some kind,
not the string captured by the regular expression.
We’ll work through each of these points before we move onto the next step in
the scenario.
Getting the Words Right
We want to clarify the wording before we do anything else, so let’s think about
how we could make the code in the step definition read more like the text in
the step. We could go back and reword the step to say something like Given an
Account with a balance of $100. In reality, though, the only way that an account
would have a balance is if someone deposited funds into it. So, let’s change
the way we talk to the domain model inside our step definition to reflect that:
Download step_definitions_inside/03/features/step_definitions/steps.rb
class Account
def deposit(amount)
end
end
Given /^I have deposited \$(\d+) in my account$/ do |amount|
my_account = Account.new
my_account.deposit(amount.to_i)
end
That seems better.
There’s something else in the wording that bothers us. In the step, we talk
about my account, which implies the existence of a protagonist in the scenario
who has a relationship to the account, perhaps a Customer. This is a sign that
we’re probably missing a domain concept. However, until we get to a scenario
where we have to deal with more than one customer, we’d prefer to keep
things simple and focus on designing the fewest classes we need to get this
scenario running. So, we’ll park this concern for now.
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• 115
Telling the Truth
Now that we’re happier with the interface to our Account class, we can resolve
the next issue from our code review. After we’ve deposited the funds in the
account, we can check its balance with an assertion:
Download step_definitions_inside/04/features/step_definitions/steps.rb
Given /^I have deposited \$(\d+) in my account$/ do |amount|
my_account = Account.new
my_account.deposit(amount.to_i)
my_account.balance.should eq(amount.to_i),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
We’ve used an RSpec assertion here, but if you prefer another assertion library,
feel free to use that. It might seem odd to put an assertion in a Given step, but
it communicates to future readers of this code what state we expect the system
to be in once the step has run. We’ll need to add a balance method to the Account
so that we can run this code:
Download step_definitions_inside/04/features/step_definitions/steps.rb
class Account
def deposit(amount)
end
def balance
end
end
Notice that we’re just sketching out the interface to the class, rather than
adding any implementation to it. This way of working is fundamental to outside-in development. We try not to think about how the Account is going to
work yet but concentrate on what it should be able to do.
Now when we run the test, we get a nice helpful failure message:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
Expected the balance to be 100 but it was
(RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/steps.rb:15
features/cash_withdrawal.feature:3
When I request $20
Then $20 should be dispensed
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
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• Chapter 7. Step Definitions: On the Inside
1 scenario (1 failed)
3 steps (1 failed, 2 skipped)
0m0.002s
Now our step definition is much more robust, because we know it will sound
an alarm bell if it isn’t able to deposit the funds into the account as we’ve
asked it to do. Adding assertions to Given and When steps like this means that
if there’s ever a regression later in the project, it’s much easier to diagnose
because the scenario will fail right where the problem occurs. This technique
is most useful when you’re sketching things out; eventually, we’ll probably
move this check further down the testing stack into a unit test for the Account
and take it out of the step definition.
Doing the Simplest Thing
We’re at a decision point here. We’ve effectively finished implementing our
first step definition, but we can’t move on to the next one until we’ve made
some changes to the implementation of the Account class so that the step
passes.
You are
here
Implement
next step
definition
Features
System
Write unit
tests for
Account
It’s tempting to pause here, move the Account class into a separate file, and
start driving out the behavior we want using unit tests. We’re going to try to
resist that temptation for now and stay on the outside of the Account class. If
we can get a full tour through the scenario from this perspective, we’ll be
more confident in the design of the class’s interface once we do step inside
and start implementing it.
So, we’ll make a very simple implementation in the Account class that’s obviously incomplete but is just right enough to make this first step pass. Think
of this like putting up scaffolding on a construction site: we’re going to take
it down eventually, but it will help things to stand up in the meantime.
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Change Account to look like this, and the first step should pass:
Download step_definitions_inside/05/features/step_definitions/steps.rb
class Account
def deposit(amount)
@balance = amount
end
def balance
@balance
end
end
Good. We still have one issue left on our list, which is the duplication of the
calls to to_i. Now that our step is passing, we can do that refactoring with
confidence.
7.2
Removing Duplication with Transforms
Another issue we have with this step definition is that we have to convert the
string captured by the regular expression into an integer. In fact, now that
we’ve added an assertion, we’ve had to do it twice. As our test suite grows,
we can imagine these calls to to_i littering our step definitions. Even these
four characters count as duplication, so let’s stamp them out.
To do this, we’re going to learn about a new Cucumber method, called Transform.
Transforms work on captured arguments. Each transform is responsible for
converting a certain captured string and turning it into something more
meaningful. For example, we can use this transform to take a matched argument that contains a number and turn it into a Ruby Fixnum integer:
Download step_definitions_inside/06/features/step_definitions/steps.rb
Transform /^\d+$/ do |number|
number.to_i
end
We define the transform by giving Cucumber a regular expression that
describes the argument we’re interested in transforming. Notice that we’ve
used the ^ and $ to anchor the transform’s regular expression to the ends of
the captured string. This is really important, because we want our transform
to match only captures that are numbers, not just captures that contain a
number somewhere in them.
When Cucumber matches a step definition, it checks for any transforms that
match each argument. When an argument matches a transform, Cucumber
passes the captured string to the transform’s block, and the result of running
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the block is what’s then yielded to the step definition. This is shown in Figure
6, Transforms: how do they work?, on page 119.
With the transform in place, we can now remove the duplicated calls to to_i
in our step definition:
Download step_definitions_inside/06/features/step_definitions/steps.rb
Given /^I have deposited \$(\d+) in my account$/ do |amount|
my_account = Account.new
my_account.deposit(amount)
my_account.balance.should eq(amount),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
Great! That code looks much cleaner and easier to read. Introducing the
transform has brought in a new kind of duplication, though. The regular
expression that we use to capture the number is now duplicated: we have \d+
both in the step definition and in the transform’s definition. This could be a
problem if we wanted, for example, to start using cents as well as dollars in
our features; we’d have to change the regular expression in the step definition
and in the transform. Fortunately, Cucumber allows us to define the regular
expression once, in the transform, and then reuse it in the step definition,
like this:
Download step_definitions_inside/07/features/step_definitions/steps.rb
CAPTURE_A_NUMBER = Transform /^\d+$/ do |number|
number.to_i
end
Given /^I have deposited \$(#{CAPTURE_A_NUMBER}) in my account$/ do |amount|
my_account = Account.new
my_account.deposit(amount)
my_account.balance.should eq(amount),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
We store the result of calling Transform in the constant CAPTURE_A_NUMBER and
then use that constant as we build the regular expression in the step definition. As well as making it easier to change and reuse this capturing regular
expression in the future, this refactoring makes it more obvious to someone
reading the step definition that this argument will be transformed.
We can tidy this up a little further by moving the dollar sign into the transform’s capture. This makes the code more cohesive, because we’re bringing
together the whole regular expression statement for capturing the amount of
funds deposited. It also gives us the option to capture other currencies in the
future.
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Removing Duplication with Transforms
• 119
Step
nition
Regular Expression
Captured
Argument
Captured
Argument
...
Transform
Transform
...
nition
Ruby Code Block
Figure 6—Transforms: how do they work?
Download step_definitions_inside/08/features/step_definitions/steps.rb
CAPTURE_CASH_AMOUNT = Transform /^\$(\d+)$/ do |digits|
digits.to_i
end
Given /^I have deposited (#{CAPTURE_CASH_AMOUNT}) in my account$/ do |amount|
my_account = Account.new
my_account.deposit(amount)
my_account.balance.should eq(amount),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
Notice that we’ve used a capture group inside the transform to separate the
numbers from the currency symbol. This is how we tell Cucumber that we’re
interested in transforming only that part of the capture we’ve been passed,
so that’s all that will be passed into our block. If we wanted to capture the
currency symbol as well, we could put another capture group around it, and
it would be yielded to the transform’s block as another argument:
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Transform /^(£|\$|€)(\d+)$/ do | currency_symbol, digits |
Currency::Money.new(digits, currency_symbol)
end
Let’s take another look at our to-do list. Using the transform has cleared up
the final point from the initial code review. As we went along, we collected a
new to-do list item: that we need to implement the Account properly, with unit
tests. Let’s leave that one on the list for now and move on to the next step of
the scenario.
7.3
Adding Custom Helper Methods to the World
We’ve implemented the first step of our scenario to set up an account with a
sufficient balance that the withdrawal should work. After all that talking
about transforms, it’s hard to remember exactly what we need to do next, but
we can always rely on cucumber to remind us where we are:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I request $20
TODO (Cucumber::Pending)
./features/step_definitions/steps.rb:28
features/cash_withdrawal.feature:4
Then $20 should be dispensed
1 scenario (1 pending)
3 steps (1 skipped, 1 pending, 1 passed)
0m0.002s
The first step is passing as we’d expect, and the second one is failing with a
pending message. So, our next task is to implement the step to simulate a
customer withdrawing cash from the ATM. Here’s the empty step definition:
Download step_definitions_inside/09/features/step_definitions/steps.rb
When /^I request \$(\d+)$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
First we can reuse the transform we created earlier to translate the cash
amount, captured as a string by Cucumber, into a number:
When /^I request (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
pending # express the regexp above with the code you wish you had
end
We need somewhere to withdraw the cash from, which means we need to
bring a new actor into this scenario. This new class is going to handle our
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Adding Custom Helper Methods to the World
• 121
request to withdraw cash from our account. If we walked into a bank in real
life, that role would be played by a teller. Thinking outside-in again, let’s
sketch out the code we’d like:
When /^I request (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
teller = Teller.new
teller.withdraw_from(my_account, amount)
end
That looks pretty good. The teller will need to know which account to take
the cash from and how much to take. There’s a little inconsistency creeping
into the language again, though: the step definition talks about requesting
the cash, but in the code we’re withdrawing it. Withdraw is the term we use
most often, so let’s change the text in the scenario to match.
Download step_definitions_inside/10/features/cash_withdrawal.feature
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I withdraw $20
Then $20 should be dispensed
Download step_definitions_inside/10/features/step_definitions/steps.rb
When /^I withdraw (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
teller = Teller.new
teller.withdraw_from(my_account, amount)
end
That’s better. Now the language in the scenario more closely reflects what’s
going on in the code beneath it. Run cucumber again, and you should be
prompted to create a Teller class. Let’s create one:
Download step_definitions_inside/10/features/step_definitions/steps.rb
class Teller
def withdraw_from(account, amount)
end
end
Again, we’ve just sketched out the interface for now, without adding any
implementation. With that in place, try running cucumber again:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I withdraw $20
undefined local variable or method ‘my_account’ for
#<Object:0x63756b65> (NameError)
./features/step_definitions/steps.rb:32
features/cash_withdrawal.feature:4
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Then $20 should be dispensed
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
3 steps (1 failed, 1 skipped, 1 passed)
0m0.003s
A-ha. We defined my_account in the first step definition, but when we tried to
use it in the second step definition, Ruby can’t see it. How can we make
my_account available to both step definitions? The answer lies in understanding
something fundamental about how Cucumber executes step definitions.
Storing State in the World
Just before it executes each scenario, Cucumber creates a new object. We
call this object the World. The step definitions for the scenario execute in the
context of the World, effectively as though they were methods of that object.
Just like methods on a regular Ruby class, we can use instance variables to
pass state between step definitions.
Here’s how the code looks with my_account stored as an instance variable in
the step definition:
Given /^I have deposited (#{CAPTURE_CASH_AMOUNT}) in my account$/ do |amount|
@my_account = Account.new
@my_account.deposit(amount)
@my_account.balance.should eq(amount), "Expected the balance to be #{amount}"
end
When /^I withdraw (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
teller = Teller.new
teller.withdraw_from(@my_account, amount)
end
Try it. It works!
This solution is OK, but we don’t really like leaving instance variables in step
definitions like this. The problem with instance variables is that, if you don’t
set them, they just return nil. We hate nils, because they creep around your
system, causing weird bugs that are hard to track down. For example, if
someone were to later come along and use the second step definition in
another scenario where they hadn’t already set @my_account, they’d end up
passing a nil into Teller#withdraw_from.
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Adding Custom Helper Methods to the World
• 123
We’re going to show you a quick refactoring to get rid of the instance variable
from the step definition, by pushing the code that creates the Account into a
helper method.
Creating Custom Helper Methods
In a regular class we’d avoid nils by putting the instance variables behind an
accessor method, like this:
def my_account
@my_account ||= Account.new
end
Using ||= ensures that the new Account will be created only once and then
stored in an instance variable. You can do the same in Cucumber. To add
custom methods to the World, you define them in a module and then tell
Cucumber you want them to be mixed into your World. Here’s what we need
to do:
Download step_definitions_inside/11/features/step_definitions/steps.rb
module KnowsMyAccount
def my_account
@my_account ||= Account.new
end
end
World(KnowsMyAccount)
We defined my_account on a module called KnowsMyAccount and then told Cucumber to mix that module into our World by calling Cucumber’s special World
method. As usual, we’ve done all this inline in the step definition file for now,
but we’re going to tidy it away soon.
This means we can get rid of the code that initializes the Account from the first
step definition, and we can get rid of the instance variable, so the step definitions go back to using my_account again:
Download step_definitions_inside/11/features/step_definitions/steps.rb
Given /^I have deposited (#{CAPTURE_CASH_AMOUNT}) in my account$/ do |amount|
my_account.deposit(amount)
my_account.balance.should eq(amount),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
When /^I withdraw (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
teller = Teller.new
teller.withdraw_from(my_account, amount)
end
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This time my_account won’t use a local variable in the step definition, but it will
call our helper method instead. With this change in place, run cucumber, and
everything should be passing.
Customizing the World
Our second step is passing now, so let’s take a break from the example to
learn a bit more about the World.
The main way you’ll use the World is by extending it with modules of code that
support your step definitions by performing common actions against your
system:
module MyCustomHelperModule
def my_helper_method
...
end
end
World(MyCustomHelperModule)
In this case, you’ll be extending a World object that Cucumber has created for
you. By default, Cucumber creates each World by simply calling Object.new, but
you can override this and use a different class if you need to, by passing a
block to the World method:
class MySpecialWorld
def some_helper_method
# …
end
end
World { MySpecialWorld.new }
Whatever class you use for your worlds, Cucumber always mixes in the
module Cucumber::RbSupport::RbWorld, which contains various helper methods you
can use to talk to Cucumber from your step definitions. The method pending
that we’ve used a few times already in the book is an example of this. There
are explanations of many of these methods scattered throughout the book,
but if you want a complete reference of them, the best thing to do is look up
the API documentation1 for Cucumber::RbSupport::RbWorld.
You can discover all the modules that are mixed into the world by calling puts
self from within a step definition. A list of modules will be printed to the output.
And because Cucumber and RSpec are friends, you’ll find that Cucumber
1.
http://cukes.info/cucumber/api/ruby/latest/Cucumber/RbSupport/RbWorld.html
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automatically mixes in RSpec’s RSpec::Matchers if it can see that you’re using
the RSpec gem.
Remember that a new world is created for each scenario, so it is destroyed
at the end of the scenario. This helps isolate scenarios from one another,
because any instance variables set during one scenario will be destroyed
along with the world in which they were created when the scenario ends.
Designing Our Way to the Finish Line
Back in the real world, we were trying to get our final step to pass. When we
run cucumber, we can see that the first two steps are passing, and the final
one is pending. Almost there! Let’s take a look at that last step definition:
Download step_definitions_inside/11/features/step_definitions/steps.rb
Then /^\$(\d+) should be dispensed$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
The big question here is: where will the cash be dispensed? Which part of the
system can we examine for evidence of whether it doled out the readies? It
seems as if we’re missing a domain concept. In the physical ATM, the cash
will end up poking out of a slot on the ATM, something like this:
Download step_definitions_inside/12/features/step_definitions/steps.rb
Then /^(#{CAPTURE_CASH_AMOUNT}) should be dispensed$/ do |amount|
cash_slot.contents.should == amount
end
That looks good. When we hook our code up to the real hardware, we’re going
to need some way of talking to it, and this object will work fine as a test double
in the meantime. Let’s start running cucumber to drive this out. First it tells us
that we need to define the cash_slot method, of course. Let’s add that method
to our helper module and rename the module to reflect its new role.
Download step_definitions_inside/12/features/step_definitions/steps.rb
module KnowsTheDomain
def my_account
@my_account ||= Account.new
end
def cash_slot
@cash_slot ||= CashSlot.new
end
end
World(KnowsTheDomain)
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Asking the Operator
One great example of the methods built into Cucumber::RbSupport::RbWorld is the ask method.
You can call ask from a step definition, and Cucumber will pause the test execution
to ask the operator who’s running the tests a question. This is useful in a situation
where you still want to use Cucumber to document a step that’s hard or impossible
to automate—just ask a human instead!
We run cucumber again, and this time it wants us to define the CashSlot class,
so let’s go ahead and do as we’re told. Again, we just build a sketch of the
interface we want to use, with minimal implementation:
Download step_definitions_inside/12/features/step_definitions/steps.rb
class CashSlot
def contents
raise("I'm empty!")
end
end
Now when you run cucumber, you’ll see we’ve moved closer to our goal: all the
classes and methods are wired up, and our final step is failing just because
there’s no cash coming out of the CashSlot:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I withdraw $20
Then $20 should be dispensed
I’m empty! (RuntimeError)
./features/step_definitions/steps.rb:19
./features/step_definitions/steps.rb:55
features/cash_withdrawal.feature:5
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
3 steps (1 failed, 2 passed)
0m0.004s
To get this last step to pass, someone needs to tell the CashSlot to dispense the
cash when the customer makes a withdrawal. It’s the Teller who’s in charge
of the transaction, but at the moment he doesn’t know anything about the
CashSlot. We’ll use dependency injection to pass the CashSlot in to Teller’s constructor. Now we can imagine a new CashSlot method that the Teller can use to tell
it to dispense the cash:
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Download step_definitions_inside/13/features/step_definitions/steps.rb
class Teller
def initialize(cash_slot)
@cash_slot = cash_slot
end
def withdraw_from(account, amount)
@cash_slot.dispense(amount)
end
end
This seems like the simplest implementation of Teller that we need to get the
scenario to pass. It’s odd that when we designed this method from the outside
we thought we’d need the account parameter, but now we don’t seem to need
it. Let’s stay focused, though: we’ll make a note on our to-do list to look into
this later and carry on getting this step to pass.
There are two changes we need to make now. We need to add the new dispense
method to CashSlot, and we have to change the second step definition to create
the Teller correctly:
When /^I withdraw (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
teller = Teller.new(cash_slot)
teller.withdraw_from(my_account, amount)
end
This call to Teller.new seems out of place in a step definition now. All our other
classes are created inside helper methods in the World, so let’s do the same
here:
Download step_definitions_inside/13/features/step_definitions/steps.rb
module KnowsTheDomain
def my_account
@my_account ||= Account.new
end
def cash_slot
@cash_slot ||= CashSlot.new
end
def teller
@teller ||= Teller.new(cash_slot)
end
end
World(KnowsTheDomain)
This means our step definition becomes a lot less cluttered:
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Download step_definitions_inside/13/features/step_definitions/steps.rb
When /^I withdraw (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
teller.withdraw_from(my_account, amount)
end
The step definition code all reads very nicely now. Pushing some of the details
down into our World module means the step definition code is at a higher level
of abstraction. This makes it less of a mental leap when you come into the
step definitions from a business-facing scenario, because the code doesn’t
contain too much detail.
This scenario isn’t going to pass until we do some work on our CashSlot, though.
Run cucumber, and you’ll see that it’s missing the dispense method. A simple
implementation of CashSlot should get this working:
Download step_definitions_inside/13/features/step_definitions/steps.rb
class CashSlot
def contents
@contents or raise("I'm empty!")
end
def dispense(amount)
@contents = amount
end
end
Run cucumber one last time, and you should see the scenario pass:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I withdraw $20
Then $20 should be dispensed
1 scenario (1 passed)
3 steps (3 passed)
0m0.002s
Excellent! Go and grab a drink—then we can sit down, review the code, and
do some refactoring.
7.4
Organizing the Code
Before we finish this session, let’s be kind to our future selves and tidy up a
little. As we worked, we just created everything we needed inline in our
features/step_definitions/step.rb file. We’ll move most of that stuff out of there, and
put it into a more conventional place. Here’s a list of what we’d like to fix:
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Organizing the Code
• 129
• The application’s domain model classes should go into a lib directory in
the root of the project.
• The KnowsTheDomain module can move into its own file.
• The transform can also move into its own file.
• The steps file can be split to organize the step definitions better. This is
arguably unnecessary for a project with only three step definitions, but
we’ll do it anyway to illustrate how we’d do this on a bigger project.
Separating the Application Code
It’s conventional in Ruby projects to store the system’s code in a lib directory
in the root of the project. We need a name for our application too, since
another convention is that the entry point to the lib folder is a single file named
after your application. Our company is trying to stand out from the crowd
with the brand name NiceBank, so create a file lib/nice_bank.rb and move the
three classes, Account, Teller, and CashSlot, into there.
Now replace the code you just took out of steps.rb with a line to load the files
from the lib directory:
Download step_definitions_inside/14/features/step_definitions/steps.rb
require File.join(File.dirname(__FILE__), '..', '..', 'lib', 'nice_bank')
Save the files and run cucumber.
This works, but it isn’t perfect. Loading the application code is something we
want to do right at the start of the test run, before Cucumber even starts
looking at the step definitions. Fortunately, Cucumber gives us another special
folder where we can do just that.
Booting the Cucumber Environment
When Cucumber first starts a test run, before it loads the step definitions, it
loads the files in a directory called features/support. We haven’t needed to use
this directory so far in the book, because our examples have been so simple.
The support directory is for code that supports the step definitions so that the
step definitions themselves stay simple and easy to read.
Just like features/step_definitions, Cucumber will load all the Ruby files it finds in
features/support. This is convenient, because it means you don’t need to pepper
require statements everywhere, but it does mean that the precise order in which
files are loaded is hard to control. In practice, this means you can’t have
dependencies between files in the support directory, because you can’t expect
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that another file will have already been loaded. There is one exception to that,
a special file called env.rb
The file features/support/env.rb is always the very first file to be loaded when
Cucumber starts a test run. You use it to prepare the environment for the
rest of your support and step definition code to operate. Loading our application is pretty fundamental to the test run, so move the require statement into
your very first features/support/env.rb file:
Download step_definitions_inside/15/features/support/env.rb
require File.join(File.dirname(__FILE__), '..', '..', 'lib', 'nice_bank')
Run cucumber, and everything should still pass.
Transforms and World Module
We should also tidy away the transform and the world module. Create a file
called features/support/transforms.rb and move the transform out of steps.rb and into
there. It’s useful to keep the transforms together like this because when we
make changes to them, we can read all the other transforms to make sure
everything is consistent. Run cucumber, and everything should still pass.
Now let’s take the KnowsTheDomain module and the call to World and move them
into a new file, called features/support/world_extensions.rb. As we add more methods
to our World, we would split them into multiple modules, each in their own
file; however, this is fine for now.
Organizing Our Step Definitions
We’ve managed to get this far with a single file of step definitions called steps.rb,
and for a project of this size, we might well stick with a single file for a while
longer. As the number of step definitions starts to grow, we’ll want to split
up the files so that the code is more cohesive. We’ve found that our favorite
way to organize step definition files is to organize them with one file per domain
entity. So, in our example, we’d have three files:
features/step_definitions/account_steps.rb
features/step_definitions/teller_steps.rb
features/step_definitions/cash_slot_steps.rb
For the time being, each of those files will contain only a single step definition,
but now we have room to grow.
Dry Run and env.rb
As we start to move files around, it’s useful to test that everything still
matches using cucumber --dry-run. A dry run aims to parse your features and
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What We Just Learned
• 131
step definitions but not actually run any of them. This is much faster than
a real test run if you just want to print off your features or check for undefined
steps with the usage formatter.
The main difference between a normal run and a dry run of cucumber is that
a dry run will not boot your environment, so env.rb will not be loaded. This
means you need to be a little bit careful how you lay out your files:
• Make sure that the other files in support can be loaded with or without
env.rb having been loaded.
• Put all the slow stuff in env.rb so that a dry run can start quickly.
Get used to using dry-run, especially with the usage formatter, to help refactor
your scenarios and step definitions with confidence.
7.5
What We Just Learned
It might seem like the system we’ve been building here is just a toy. There
aren’t any concrete components that a user could interact with yet: our CashSlot
is just a plain old Ruby class, and there aren’t any buttons for the user to
push. What we do have, though, are the beginnings of a domain model and
a greater understanding of the problem. Outside-in doesn’t always mean
starting with the user interface; it means starting with the outside of whatever
you want to discover.
We know it isn’t always possible to work like this. You’ll often be adding tests
to a legacy system or working on a project where the user interface is already
well-defined by the time you’re asked to develop the code. Even in these situations, trying to model your domain in Ruby classes will help your own
understanding and also make the test code more maintainable in the long
term.
Here are some of the more concrete subjects we’ve covered in this chapter:
• Transforms help with maintainability by removing annoying duplicate
code to process captured arguments from steps. They also give names to
the useful parts of your regular expressions.
• Ruby code that supports the step definitions can go into features/support,
which is loaded before the step definitions.
• The file features/support/env.rb is loaded first of all, and that’s where you need
to boot up your application. This file isn’t loaded during a dry run.
• It’s good practice to organize step definition files with one file per domain
entity.
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• Chapter 7. Step Definitions: On the Inside
• Step definitions execute in the context of an object called the World. You
can pass state between steps using instance variables and mix in helper
methods defined in Ruby modules.
By adding our own World module, we’ve made the step definition code easier
to read, and we’ve started to decouple the step definitions from the system.
The benefit of this decoupling will come later as the system itself evolves. In
fact, in the next chapter, we’ll show you how we can introduce a web user
interface for withdrawing the cash without having to change a line in the step
definitions.
Try This
There are lots of places you could take this example now that we have it up
and running. Here’s one idea for you to try:
The Big Rewrite
Now that we’ve discovered the domain model together, why not see whether
you can do it again, for practice? Delete everything except the feature, the
transform, and the step definitions. Then delete the body of each step definition, and change it back to pending. Close the book, run cucumber, and off you
go!
Try to forget about what we did, and enjoy the process of discovering a domain
model for yourself.
Bug Hunt
There’s one remaining item on our to-do list, reminding us that we need to
investigate why we originally designed the Teller#withdraw_from method to take
two parameters, but we’re using only one of them.
See whether you can figure out what this inconsistency means, and think
about what changes you’d like to make in order to resolve it. Play with the
code and try some solutions. We’ll work on this issue at the beginning of the
next chapter, so you won’t have long to wait if you’re not sure of the answer.
Edge Cases
We have a single scenario here for the happy path through the process of
withdrawing cash. Can you think of some simple variations on the scenario
that would cause a different outcome? For example, what would happen if
your account had a lower balance?
Write your new scenarios out in the same cash_withdrawal.feature file, and if you’re
up for the challenge, have a go at automating them.
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CHAPTER 8
Support Code
In the previous chapter, we started working through an example of how to
use Cucumber to build a real application, outside-in. The system we’re
building is an Automated Teller Machine (ATM) for a bank, and we used
Cucumber to help us design a simple domain model that satisfied this
scenario:
Download support_code/01/features/cash_withdrawal.feature
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I withdraw $20
Then $20 should be dispensed
The code we’ve written makes the scenario pass, but the system isn’t really
of any use yet: there’s no external interface for a user to interact with, just a
handful of Ruby classes. Now we’re going to fix that, by wrapping the domain
model with a user interface where the user can request the amount of cash
they want to withdraw.
In this chapter, we’re going to focus mostly on the code in the features/support
folder. This is the lowest level of your test code, where it connects or couples
to your actual application. If this coupling is well-engineered, your tests will
be a pleasure to modify as your project grows. If the coupling is too tight,
your tests will be brittle and break any time anything moves. That’s why we
created a separation layer between the step definitions and the system using
a module of helper methods mixed into the World. This separation layer provides
just the decoupling we’ll need as we start to introduce a user interface.
Before we get started with the user interface, we have one item left on our
to-do list we need to check off first.
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8.1
• Chapter 8. Support Code
Fixing the Bug
Sometimes the signals you’ll get from the code that something is wrong are
pretty faint. We always try to keep a to-do list handy and write down everything
that concerns us as we go. That way, we can stay focused on the task at hand
but know that we’ll get a chance to check over and clean up any inconsistencies before we move onto the next task.
As we were finishing off the last scenario, we noticed that Teller#withdraw_from
takes two arguments, but only one of them was used in the method to make
the scenario pass. This inconsistency means that something is wrong, but
we need to investigate further to know what we need to do about it. Let’s take
a look at the code that uses the method:
Download support_code/01/features/step_definitions/teller_steps.rb
When /^I withdraw (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
teller.withdraw_from(my_account, amount)
end
It seems pretty obvious what we intended to happen here. The Teller should
take the specified amount of money out of the account and hand it to the CashSlot.
So, how did we manage to make the scenario pass without having to do anything to the account when we implemented that method? Let’s take another
look at the scenario:
Download support_code/01/features/cash_withdrawal.feature
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I withdraw $20
Then $20 should be dispensed
A-ha! There’s nothing here that actually checks that the balance of the account
has been reduced to $80. It’s a good thing we caught this now—our code
would have been handing out cash to customers for free!
Let’s tack on this extra outcome as another Then step:
Download support_code/02/features/cash_withdrawal.feature
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I withdraw $20
Then $20 should be dispensed
➤
And the balance of my account should be $80
Run cucumber and paste the snippet for the new step definition into the file
features/step_definitions/account_steps.rb:
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• 135
Matt says:
That’s Not a Bug; It’s Just a Missing Scenario
One of the wonderful things I discovered when I first used Cucumber to build a
complete application from the outside-in was when we started manual exploratory
testing and discovered some bugs. Almost without exception, every one of those bugs
could be traced back to a gap in the Cucumber scenarios we’d written for that part
of the system. Because we’d written the scenarios collaboratively, with businesspeople
and developers working together to get them right, it wasn’t anybody’s fault that there
was a bug. It was just an edge case we hadn’t originally anticipated.
In my experience, bugs are a big source of friction and unhappiness in software teams.
Businesspeople blame them on careless developers, and developers blame them on
inadequate requirements from the businesspeople. Actually they’re just a natural
consequence of software development being a really complex endeavor. Using Cucumber really helped the team see that closing these gaps is everyone’s job. The blaming
just didn’t happen, and we were a much happier team as a result.
Download support_code/02/features/step_definitions/account_steps.rb
Given /^I have deposited (#{CAPTURE_CASH_AMOUNT}) in my account$/ do |amount|
my_account.deposit(amount)
my_account.balance.should eq(amount),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
Then /^the balance of my account should be \$(\d+)$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
We can tidy up the regular expression for the step definition using the
transform we created in the previous chapter and duplicate the assertion
from the previous step definition:
Download support_code/03/features/step_definitions/account_steps.rb
Given /^I have deposited (#{CAPTURE_CASH_AMOUNT}) in my account$/ do |amount|
my_account.deposit(amount)
my_account.balance.should eq(amount),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
➤
➤
Then /^the balance of my account should be (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
my_account.balance.should eq(amount),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
We’ll make a note on our to-do list to tidy up that duplication and carry on
trying to fix this bug. Run cucumber now to see whether we have it trapped:
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Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I withdraw $20
Then $20 should be dispensed
And the balance of my account should be $80
Expected the balance to be 80 but it was 100
(RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/account_steps.rb:9
features/cash_withdrawal.feature:6
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
4 steps (1 failed, 3 passed)
0m0.003s
Great—the bug has been caught by our scenario. Just as we suspected, the
account’s balance remains untouched by the withdrawal. But not for long!
Crack open lib/nice_bank.rb, and take a look at our Teller class:
Download support_code/03/lib/nice_bank.rb
class Teller
def initialize(cash_slot)
@cash_slot = cash_slot
end
def withdraw_from(account, amount)
@cash_slot.dispense(amount)
end
end
Change the withdraw_from method to tell the account what to do:
Download support_code/04/lib/nice_bank.rb
class Teller
def initialize(cash_slot)
@cash_slot = cash_slot
end
def withdraw_from(account, amount)
➤
account.debit(amount)
@cash_slot.dispense(amount)
end
end
Now when we run cucumber, we’re told we need to create this new method on
the Account. On a real project, we’d drop down a gear at this point and start
writing unit tests for the Account class to drive out that method. We don’t mind
sketching out interfaces to classes with a few basic method stubs with only
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Cucumber to back us up, but as soon as we start adding interesting behavior
to a class, we like to make sure that behavior has been specified in a unit
test. The RSpec Book [CADH09] and Growing Object-Oriented Software, Guided
by Tests [FP09] both do a great job of explaining this balance with plenty of
examples, but since this book is focused on Cucumber, we’re going to gloss
over this step and carry on.
Find the Account class in lib/nice_bank.rb and change it to look like this:
Download support_code/05/lib/nice_bank.rb
class Account
def deposit(amount)
@balance = amount
end
def balance
@balance
end
def debit(amount)
@balance -= amount
end
end
We’ve implemented a new method called debit that decrements the @balance by
the given amount. Let’s see whether we’ve managed to fix the bug:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
When I withdraw $20
Then $20 should be dispensed
And the balance of my account should be $80
1 scenario (1 passed)
4 steps (4 passed)
0m0.002s
Hooray, we did it! Now it’s time for some refactoring before we move on.
Reviewing and Refactoring
In Extreme Programming Explained [Bec00], Kent Beck gives four criteria for
a simple design. In order, with the most important first, they are as follows:
1.
2.
3.
4.
Passes all the tests
Reveals all the intention
Contains no duplication
Uses the fewest number of classes or methods
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Let’s review our current code against those four criteria. It’s been driven from
a single test made from a single Cucumber scenario that is passing, so that’s
rule 1 taken care of. How about rule 2? Revealing intention is essentially
about how things are named, which matters to us a great deal. Let’s take a
look at the methods on our Account class:
Download support_code/05/lib/nice_bank.rb
class Account
def deposit(amount)
@balance = amount
end
def balance
@balance
end
def debit(amount)
@balance -= amount
end
end
Reflecting on it, it’s confusing that we’ve used the two method names deposit
and debit. Really, we’d either like to see deposit and withdraw or credit and debit,
but not a combination of the two. Which pair is more appropriate for our Account
class?
We spend a bit of time chatting with one of our domain experts, and it becomes
clear that credit and debit are the right names for the methods on Account. In
fact, deposit is something you’d more likely ask a Teller to do for you. These
conversations happen all the time as you start to establish a ubiquitous language, and you’ll find they become easier and easier as your knowledge of
the domain, and the ubiquitous language you all use to discuss it, grows.
We’re going to rename the Account#deposit method to Account#credit. Since our
test is nice and fast, we can just rename the method and see what breaks:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given I have deposited $100 in my account
undefined method ‘deposit’ for #<Account:0x63756b65> (NoMethodError)
./features/step_definitions/account_steps.rb:2
features/cash_withdrawal.feature:3
When I withdraw $20
Then $20 should be dispensed
And the balance of my account should be $80
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
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1 scenario (1 failed)
4 steps (1 failed, 3 skipped)
0m0.003s
In Refactoring: Improving the Design of Existing Code [FBBO99], this technique
(make the change, see what breaks) is called leaning on the compiler. Since
we don’t have a compiler in Ruby programs, we have to settle for leaning on
the tests. From the backtrace, it looks like we need to change line 2 of
features/step_definitions/account_steps.rb. Go ahead and change that, and run cucumber
again.
Our scenario is passing, but we’re not quite done yet! The language in the
step is now inconsistent with the code inside the step definition we’ve just
changed:
Download support_code/07/features/step_definitions/account_steps.rb
Given /^I have deposited (#{CAPTURE_CASH_AMOUNT}) in my account$/ do |amount|
my_account.credit(amount)
my_account.balance.should eq(amount),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
In the step, we’re still using the term deposited, but now we’re crediting the
account in the Ruby code underneath. How much does this matter? Perhaps
not much, but we’d prefer our test code to be as transparent as possible. After
another discussion with our domain expert, we decide to reword the step to
read Given my account has been credited with $100. We’ll change the feature and the
underlying step definition:
Download support_code/08/features/cash_withdrawal.feature
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
Then $20 should be dispensed
And the balance of my account should be $80
Download support_code/08/features/step_definitions/account_steps.rb
Given /^my account has been credited with (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
my_account.credit(amount)
my_account.balance.should eq(amount),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
Looking at this step definition now, it doesn’t make sense anymore to check
that the balance is the same as the amount credited. If this step definition
were used in another scenario that involved other credit or debit transactions
before this one, the balance might not be the same as the amount credited,
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• Chapter 8. Support Code
Test Automation Is Software Development
You’ll have noticed the painstaking care with which we’ve moved back and forth
between the features, the step definitions, and the system itself, keeping everything
as clean and consistent as we can. You might be wondering whether we honestly
work this way in our everyday practice. We certainly try to do so. We’ve alluded to
this earlier in the book, but we feel like it’s time to make the point clearly: if you’re
writing automated tests, you’re developing software. If you value those tests enough
to have written them in the first place, you’ll want to be able to come back and change
them in the future. That means that all the same good habits we normally use to
write maintainable software apply to the test code we write too.
This important point is often missed, especially in a company where testing has
traditionally been done manually. People who specialize in testing sometimes aren’t
the best people to be automating tests, if they lack the necessary experience in software
design. Without support from people who do understand how to write maintainable
code, the team can end up with messy test code that’s hard to change. It’s around
this point that people start to realize their automated tests are actually making it
harder to change the software, not easier, and consider giving up on Cucumber altogether. Figure 7, What skills do you need to write Cucumber tests?, on page 142 shows
how software development skill becomes increasingly important as you move down
the stack from Gherkin features to support code.
Testing and software design are complementary skills, and a strong team needs a
mix of both specialties. Different people will sit at different points on this spectrum:
some people will be great testers but not at all interested in automation or programming, and some will just want to write code without thinking about how to break it.
That’s fine, but the team needs to recognize that there isn’t a clear division of responsibility when you’re working with automated tests. Everyone needs to work together
to create and maintain high-quality tests.
and that would be quite all right. So, we don’t want this assertion here any
more.
That gives us an easy way to cross off the last item on our to-do list: removing
the duplication of the balance assertion in the two-step definitions for the
account. We can simply delete the first one, because it’s no longer relevant:
Download support_code/09/features/step_definitions/account_steps.rb
Given /^my account has been credited with (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
my_account.credit(amount)
end
Then /^the balance of my account should be (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
my_account.balance.should eq(amount),
"Expected the balance to be #{amount} but it was #{my_account.balance}"
end
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Bootstrapping the User Interface
• 141
That completes our refactoring. The code is now as clear and communicative
and free of duplication as we can imagine at this stage. We’re ready to add
some new functionality.
8.2
Bootstrapping the User Interface
Now that we have a model we’re happy with, we’re going to wrap it in a simple
user interface that allows the user to specify how much cash they want to
withdraw. Even though it might not be a typical choice for a real ATM, we’re
going to use a web form. We’ll use the Sinatra1 web framework to serve our
user interface, and we’ll use the Capybara2 gem to automate it. We won’t go
into much detail about how Capybara works here, but you’ll learn much more
in Chapter 15, Using Capybara to Test Ajax Web Applications, on page 245.
We’ll start by adding the necessary gems to our project and getting the web
server up and running.
Installing the Gems
Our app is growing up. We need to install another couple of Ruby gems, so
let’s create a Gemfile to manage the project’s dependencies using Bundler.3
Download support_code/11/Gemfile
source :rubygems
gem 'sinatra', '1.3.1'
group
gem
gem
gem
end
:development do
'rspec', '2.7.0'
'cucumber', '1.1.3'
'capybara', '1.1.2'
Run the command bundle in the root of the project to install these gems.
Once the gems are installed, we can kick the tires on Sinatra by adding a few
lines to the end of lib/nice_bank.rb:
Download support_code/11/lib/nice_bank.rb
require 'sinatra'
get '/' do
'Welcome to our nice bank.'
end
1.
2.
3.
http://sinatrarb.com
http://rubygems.org/gems/capybara
For instructions on installing Bundler, see Appendix 2, Installing Cucumber, on page
299.
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• Chapter 8. Support Code
Testing
Skill
Software Design
Skill
Gherkin
Features
Step
Definitions
Support Code
Automation
Libraries
Figure 7—What skills do you need to write Cucumber tests?
If you run this file with the command bundle exec ruby lib/nice_bank.rb, you should
see Sinatra start up a web server. You can now try hitting it from a browser
at http://localhost:4567/. That’s the beginning of our user interface.
In our tests, we need to load the Capybara library and tell it where to find
our web application. Change features/support/env.rb to look like this:
Download support_code/11/features/support/env.rb
require File.join(File.dirname(__FILE__), '..', '..', 'lib', 'nice_bank')
require 'capybara/cucumber'
Capybara.app = Sinatra::Application
Sinatra::Application.set :environment, :test
We haven’t actually changed the way our tests communicate with the application, so if you run cucumber again, the scenario should still pass. Good? Time
to start building our web application.
8.3
Making the Switch
Our goal is to introduce a user interface for requesting the cash withdrawal.
We want Cucumber to cover us as we make these changes, so we need to
change how our test code interacts with the application. Up until now, all
our step definitions were talking directly to the domain model. We’re going to
change that so that some of them hit the new user interface instead (see
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Making the Switch
• 143
Figure 8, Introducing the user interface, on page 144). Which steps need to
change?
Let’s take a look at our scenario again:
Download support_code/11/features/cash_withdrawal.feature
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
Then $20 should be dispensed
And the balance of my account should be $80
We haven’t specified anything about how we do the cash withdrawal, so there’s
nothing we need to change about the scenario at all. Great! Let’s jump down
into the step definition for withdrawing cash and see what needs to change
there:
Download support_code/11/features/step_definitions/teller_steps.rb
When /^I withdraw (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
teller.withdraw_from(my_account, amount)
end
All we’re doing here is calling withdraw_from on something. Right now that
something is an instance of the Teller class in our domain model. But what if
we made teller return something else, like an object that represents the user
interface? That’s the beauty of object-oriented programming—as long as the
object understands the withdraw_from method, this step definition is going to
be happy. Let’s leave this step definition alone and drop down into our World
module:
Download support_code/11/features/support/world_extensions.rb
module KnowsTheDomain
def my_account
@my_account ||= Account.new
end
def cash_slot
@cash_slot ||= CashSlot.new
end
def teller
@teller ||= Teller.new(cash_slot)
end
end
World(KnowsTheDomain)
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• Chapter 8. Support Code
Cukes
Cukes
User Interface
Domain Model
Domain Model
Before
After
Figure 8—Introducing the user interface
What we need to do is reimplement the teller method to return a class that
knows how to automate the user interface. For now, just build an empty class
with the right method on it, and change teller to return an instance of the new
class:
Download support_code/12/features/support/world_extensions.rb
module KnowsTheUserInterface
class UserInterface
def withdraw_from(account, amount)
end
end
def my_account
@my_account ||= Account.new
end
def cash_slot
@cash_slot ||= CashSlot.new
end
def teller
@teller ||= UserInterface.new
end
end
World(KnowsTheUserInterface)
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Making the Switch
• 145
Now we’ve disconnected the action-invoking When step in our scenario from
the domain model and connected it to this new UserInterface class. We’ve also
renamed the module to reflect its new responsibility. If you run cucumber now,
you should see the scenario fail:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
Then $20 should be dispensed
I’m empty! (RuntimeError)
./lib/nice_bank.rb:30
./features/step_definitions/cash_slot_steps.rb:2
features/cash_withdrawal.feature:5
And the balance of my account should be $80
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
4 steps (1 failed, 1 skipped, 2 passed)
0m0.003s
The scenario has failed because our new support module hasn’t been wired
up to the system yet, so nothing has been found in the cash slot. Now we
have a goal: get that scenario to pass again, but this time, through the user
interface.
Designing the User Interface
So, what should this shiny new user interface look like? We gathered around
the whiteboard with our user experience team and sketched out a wireframe
for the first iteration of the cash withdrawal form. The plan is for it to look
roughly like Figure 9, Wireframe for cash withdrawal user interface, on page
146.
Let’s flesh out our UserInterface class to talk to that form:
Download support_code/13/features/support/world_extensions.rb
class UserInterface
include Capybara::DSL
def withdraw_from(account, amount)
visit '/'
fill_in 'Amount', :with => amount
click_button 'Withdraw'
end
end
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Amount:
500
Withdraw
Figure 9—Wireframe for cash withdrawal user interface
We’ve included Capybara’s DSL module in the UserInterface class to give us these
new methods that let us carry out actions on the web user interface. First we
visit the home page, then we fill_in the field labeled Amount, and finally we click
the Withdraw button. This is the design we just looked at on the wireframe,
formalized in code.
When we run cucumber against this, it’s going to fail of course, because we
haven’t built the form yet. Let’s run it anyway just to check we’re on track:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
cannot fill in, no text field, text area or password field with id, name,
or label ’Amount’ found (Capybara::ElementNotFound)
(eval):2
./features/support/world_extensions.rb:9
./features/step_definitions/teller_steps.rb:2
features/cash_withdrawal.feature:4
Then $20 should be dispensed
And the balance of my account should be $80
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
4 steps (1 failed, 2 skipped, 1 passed)
0m0.207s
OK, so Capybara is telling us that there isn’t an Amount field to fill in. Wouldn’t
it be nice to be able to see what Cucumber is seeing? We could start Sinatra
and run a manual test, but it would be more useful to see exactly what’s in
the browser when the test fails. To do this, we need to take some time out to
learn about a new feature of Cucumber.
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Using Hooks
8.4
• 147
Using Hooks
Cucumber supports hooks, which are blocks of code that run before or after
each scenario. You can define them anywhere in your support or step definition layers, using the methods Before and After.
To test them, take any Cucumber project and try adding a file features/support/hooks.rb that looks like this:
Before do
puts "Go!"
end
After do
puts "Stop!"
end
If you run cucumber, you’ll see the two messages printed in the output at the
beginning and end of the scenario. Cucumber’s Before and After hooks are a
lot like the setup and teardown methods in the xUnit family of testing tools.
The most common use of Before and After hooks is to clear up any residual
state left in external systems like databases so that each scenario starts with
the system in a known state. We’ll explain this in detail in Chapter 10,
Databases, on page 173.
Hooks are global by default, meaning they run for every scenario in your
features. If you want them to run for just certain scenarios, you need to tag
those scenarios and then use a tagged hook.
Tagged Hooks
Both Before and After accept a tag expression, which you can use to selectively
add the hook to only certain scenarios. For example, suppose you’re writing
features for the administrative area of a website. Each of the administrator
features starts with the following background:
Feature: Delete Widgets
Background:
Given I am logged in as an administrator
...
An alternative is to tag the feature and then use a Before hook to run this same
code to log in as an administrator.
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@admin
Feature: Delete Widgets
...
Before('@admin') do
user = create_user(:admin => true)
login_as user
end
Now, to run a scenario logged in as an administrator, you just have to tag
the scenario with @admin, and this code will automatically run before the steps
of the scenario. In Filtering with Tag Expressions, on page 193, we will explain
more complex tag expressions using logical operations, but a simple tag will
do for now.
Tagged hooks can be useful for ensuring technical things like external services
are started, without making too much fuss about them in the text of the
scenario itself.
Examining the Scenario
If we want it to, our hook can accept a single argument that represents the
scenario. For example, we can ask a scenario for its name:
Before do |scenario|
puts "Starting scenario #{scenario.name}"
end
We can also ask the scenario whether it failed:
After do |scenario|
puts "Oh dear" if scenario.failed?
end
For more details on the Scenario object, look at the documentation for Cucum4
ber::Ast::Scenario.
Around Hooks
Around hooks give you more power than Before and After hooks, allowing you to
actually control how many times the scenario is run. An Around hook is passed
two parameters: an object that represents the scenario and a block of code
that, when called, will run the scenario:
4.
http://cukes.info/cucumber/api/ruby/latest/Cucumber/Ast/Scenario.html
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Using Hooks
• 149
Aslak says:
Step Definitions Are Global
When you define a step definition, it is defined globally. There is no way to reduce
the scope of a step definition to certain scenarios like you can do with tagged hooks.
People occasionally ask for a way to scope step definitions in a similar way to tagged
hooks, such as making When I turn it off invoke one step definition for some scenarios
and another one for others.
This is a feature that would be easy to add to Cucumber, and one day I actually
implemented it to get some feedback from the nice people on the Cucumber mailing
list. My question was, Can anyone think of how people might misuse this? Richard
Lawrence, an old-timer on the list, answered:
Feature-coupled steps is the extreme. The more subtle issue is that the beneficial
pressure to grow a ubiquitous language goes away when it becomes too easy to say,
“Oh, that’s just another context, I’ll use the same words to mean something different
here.” Thinking about some of the conversations I’ve had coaching teams to learn
ubiquitous language, I would expect this to happen a lot.
The term “feature-coupled steps” is a term I came up with in the early days of Cucumber when I was documenting good and bad Cucumber practices in the wiki. I consider
feature-coupled steps to be a code smell since they quickly cause a lot of duplication
and do nothing to promote a ubiquitous language.
When Dan North—the originator of BDD—wrote his first BDD framework, step definitions were coupled to features. He told me the ability to have global step definitions
shared across features was one of the improvements Cucumber brought on.
In retrospect, it’s rather amusing to observe the clones and spin-offs of Cucumber
re-introducing mechanisms that we deliberately got rid of.
In Cucumber, the same sentence can mean only one thing.
Around do |scenario, block|
puts "About to run #{scenario.name}"
block.call
puts "Finished running #{scenario.name}"
end
With the extra power of Around hooks comes increased responsibility: if you
forget to call the block, your scenario won’t run at all.
Around hooks also accept tags, so you can restrict them to run for only some
scenarios, just like Before and After hooks. One great trick we’ve seen them
used for is to run the same scenario twice under different conditions, like
this:
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Around('@run_with_and_without_javascript') do |scenario, block|
Capybara.current_driver = Capybara.javascript_driver
block.call
Capybara.use_default_driver
block.call
end
Here we’ve used an Around hook that runs only on scenarios that are tagged
with @run_with_and_without_javascript. The hook runs the scenario twice, first with
Capybara set to use a driver that supports JavaScript and then again with
the default driver. You’ll learn more about Capybara itself in Chapter 15,
Using Capybara to Test Ajax Web Applications, on page 245, but this should
give you an idea of what’s possible using Around hooks.
Hooks That Run at Other Times
If you want to run code before all of your features start, the way to do that is
simply to put it into a Ruby file inside features/support. Any file in there will be
run by Cucumber before your first scenario runs.
If you want to run code after all of your features have finished, you can use
Ruby’s built-in at_exit hook, which will be run just before the Cucumber process
exits. You can write one of these hooks from anywhere, including within a
step definition, but you’ll typically use them to tear down some external system
that you’ve started from your support code.
There are two other built-in hooks in Cucumber, AfterStep and AfterConfiguration,
which we won’t go into here. For more information, refer to the documentation
for Cucumber::RbSupport::RbDsl.5
Armed with this new knowledge about hooks, let’s get back to work on our
ATM.
8.5
Building the User Interface
We can add a debugging hook to show us what’s going on in our failing
scenario. Create a file features/support/debugging.rb:
Download support_code/14/features/support/debugging.rb
After do |scenario|
save_and_open_page if scenario.failed?
end
The method save_and_open_page is provided by Capybara, but it relies on the
launchy gem that isn’t installed automatically. We’ll add it to our Gemfile:
5.
http://cukes.info/cucumber/api/ruby/latest/Cucumber/RbSupport/RbDsl.html
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• 151
Download support_code/14/Gemfile
source :rubygems
gem 'sinatra', '1.3.1'
group
gem
gem
gem
gem
end
:development do
'rspec', '2.7.0'
'cucumber', '1.1.3'
'capybara', '1.1.2'
'launchy', '2.0.5'
Now run bundle to install the new gem.
What you should see if you run cucumber now is the web page that Cucumber
can see has been saved to disk and opened up in your browser. This can be
a very helpful debugging tool. What it’s shown us is the simple greeting
message we added earlier when we first added Sinatra. We need to change
the Sinatra app to return a simple HTML form.
Download support_code/15/lib/nice_bank.rb
require 'sinatra'
get '/' do
%{
<html>
<body>
<form action="/withdraw" method="post">
<label for="amount">Amount</label>
<input type="text" id="amount" name="amount">
<button type="submit">Withdraw</button>
</form>
</body>
</html>
}
end
post '/withdraw' do
fail "I don't know how to withdraw yet, sorry"
end
We’ve hard-coded the HTML for the form right in the Sinatra web request
handler so that you can easily see what’s going on. The form contains a single
field with a label and a submit button that posts back to the server. We’ve
also added a new post request handler so that the form has somewhere to post
back to, although it’s just a stub that will raise an error if it’s called.
Try running cucumber now. If everything has gone according to plan, you’ll see
the error I don't know how to withdraw yet, sorry displayed in Cucumber’s output, and
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save_and_open_page should be showing the form, since that’s the last thing the
browser was looking at. Our next step is to implement the right code in the
post request handler to actually withdraw the cash.
Dispensing the Cash
We’ve already built a domain model, so we have a significant head start. The
class that knows how to carry out the withdrawal is Teller, so we’ll need to
create an instance of that class when we receive the posted form data on the
web server. To create an instance of the Teller, we need a CashSlot to pass to the
constructor. The slightly tricky thing about this is that we need to make sure
that the step definitions are also looking at the same instance of CashSlot;
otherwise, they won’t be able to see the cash we’ve dispensed.
We can use Sinatra’s settings to store a single instance of CashSlot where it
can be accessed by both the web application and the tests. First we’ll create
the setting and use it in the web application:
Download support_code/16/lib/nice_bank.rb
set :cash_slot, CashSlot.new
post '/withdraw' do
teller = Teller.new(settings.cash_slot)
fail "I don't know how to withdraw yet, sorry"
end
Ah, now if we want to call withdraw_from on the teller, we’ll also need an Account.
As our project progresses, we’ll probably end up determining the Account by
reading the user’s card, but at the moment our domain model doesn’t go that
far. For the time being, what we need is a way for the step definitions to be
able to say to the web application look, just trust me and use this account.
Let’s create another setting on our web application so it can share the account
with the tests. This time we won’t give it a default value, however, because
the ATM shouldn’t have a default account—it should be determined from the
user’s interactions with the ATM when they push their card into the slot and
enter their PIN. In case we forget to do this in future scenarios, we’ll cause it
to throw an error if it hasn’t been set:
Download support_code/17/lib/nice_bank.rb
set :cash_slot, CashSlot.new
set :account do
fail 'account has not been set'
end
post '/withdraw' do
teller = Teller.new(settings.cash_slot)
teller.withdraw_from(settings.account, params[:amount].to_i)
end
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• 153
Now we can try to call Teller#withdraw_from. Update your code to look like the
previous code, and run cucumber. You should see the error message from the
account setting:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
account has not been set (RuntimeError)
./lib/nice_bank.rb:55
./lib/nice_bank.rb:60
(eval):2
./features/support/world_extensions.rb:10
./features/step_definitions/teller_steps.rb:2
features/cash_withdrawal.feature:4
Then $20 should be dispensed
And the balance of my account should be $80
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
4 steps (1 failed, 2 skipped, 1 passed)
0m0.269s
We need to update our support code so that it makes use of these two
touchpoints for sharing the CashSlot and Account. For the CashSlot, we’ll change
our support module to read the web application’s setting instead of creating
its own instance:
Download support_code/18/features/support/world_extensions.rb
def cash_slot
Sinatra::Application.cash_slot
end
def teller
@teller ||= UserInterface.new
end
end
World(KnowsTheUserInterface)
Then the last thing to do is set the Account on the web application as we fill
out the withdrawal form:
Download support_code/18/features/support/world_extensions.rb
class UserInterface
include Capybara::DSL
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➤
• Chapter 8. Support Code
def withdraw_from(account, amount)
Sinatra::Application.account = account
visit '/'
fill_in 'Amount', :with => amount
click_button 'Withdraw'
end
end
This is a temporary shortcut around the process of actually authenticating
the user with their physical card and PIN, because we don’t want to worry
about that part of the process yet.
Run cucumber now, and the scenario should be passing:
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
Then $20 should be dispensed
And the balance of my account should be $80
1 scenario (1 passed)
4 steps (4 passed)
0m0.176s
Phew! We’ve managed to convert our tests to run against a web interface, and
all we needed to do was change the way our World module’s methods were
implemented. If we wanted, we could set up our tests to switch between the
two modules, giving us fast tests that go directly to the domain model and
slower, more thorough tests that go right through the user interface.
8.6
What We Just Learned
Working outside-in with Cucumber blurs the lines between testing and development. Always be ready to learn something new about the problem domain,
whether you’re deciding on the wording in a Cucumber scenario or choosing
the parameters for a method. By taking care to craft a clean interface between
your tests and the system underneath, you’ll end up with tests that can easily evolve with the system’s changing requirements.
In this chapter, we showed you how to use Cucumber to trap a bug. In
Chapter 13, Adding Tests to a Legacy Application, on page 221, we’ll talk much
more about this.
We covered the basics of creating Sinatra applications and testing them using
Capybara. There’s a whole chapter specifically on using Capybara, Chapter
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15, Using Capybara to Test Ajax Web Applications, on page 245. Sinatra is a
useful tool for testers to know about. Sometimes, when the system you’re
testing depends on an external web service that you can’t control, you’ll want
to create a test double of that external service. Sinatra is a quick and easy
way of creating such a test double.
We also showed you how to use Cucumber’s hooks to invoke Ruby code before
and after each scenario or to run them before specific scenarios using tags.
Next we’ll introduce a new problem by changing the architecture to make the
system asynchronous.
Try This
Here are some exercises for you to try for yourself.
Redesign
Our user experience aficionados have had a rethink. Early reports from user
testing are that most users don’t want to have to type in a precise amount of
money; they want to click a button with a fixed amount. Without changing
the Cucumber scenario, can you change the support code and then the user
interface itself so that the user has to click only a single button to get their
$20?
Can you add some more scenarios (and some more buttons) for other fixed
amounts?
Preventing Overdraws
We need to help our customers not to overdraw. Add a new scenario that
looks like this:
Feature: Prevent users from going overdrawn
Scenario: User tries to withdraw more than their balance
Given my account has been credited with $100
When I withdraw $200
Then nothing should be dispensed
And I should be told that I have insufficient funds in my account
Can you implement it?
Balancing Act
Our users would like to be able to check their balance from the ATM. Decide
how you’d like the user interface to be—perhaps you’ll show a menu from
which they can choose to make a withdrawal or check their balance—and
then implement this scenario:
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Feature: Display balance
Scenario: User checks the balance of an account in credit
Given my account has been credited with $100
When I check my balance
Then I should see that my balance is $100
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CHAPTER 9
Dealing with Message Queues and
Asynchronous Components
Our worked example has been pretty simplistic so far. We’re testing a single
web server process that doesn’t even have a database, and we’ve used only
a single scenario to test it. The real systems you have to work on when you
put this book down are probably much more complicated than that, with
several services interacting to deliver the behavior you’ve described in your
Cucumber features.
In this chapter, we’re going to make our system more enterprisey, splitting
the architecture into a frontend and backend so that we can show you how
to test these kinds of systems. On the way, we’ll get the chance to explain
some fundamental concepts about testing asynchronous systems.
9.1
Our New Asynchronous Architecture
In a real banking system, the ATM isn’t the only thing making debits on your
account. You might use your debit card in a restaurant or supermarket, or
you might walk into a bank and withdraw cash over the counter. You might
have written a check that gets cashed a few days later. You’ll also get credits
into your account, like when you deposit checks at the bank. The bank treats
each of these events as a transaction, which it processes some time after the
actual event has happened. Note that this kind of transaction is completely
different from a database transaction, which we’ll talk about in the next
chapter.
We’re going to change our architecture so that when the customer makes a
withdrawal from the ATM, it posts a message about the debit transaction into
a message queue. We’ll move the responsibility for processing this queue into
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a separate backend service. As the backend service works through the queue
of transactions, it will store the updated account balance in a database so
that the ATM (and our tests) can access it.
Figure 10, Enterprise messaging architecture, on page 159 shows how the new
architecture looks. The ATM posts messages about transactions into the
Transaction Queue. The Transaction Processor reads messages off that queue, reads
the existing balance from the Balance Store, and then stores the updated balance
back in the Balance Store. The ATM reads the account balance from the Balance
Store.
Let’s look at the implications this new architecture will have on how we test
the system.
9.2
How to Synchronize
In our current implementation, the debit and credit transactions are processed
synchronously by our simplistic Account class:
Download support_code/18/lib/nice_bank.rb
class Account
def credit(amount)
@balance = amount
end
def balance
@balance
end
def debit(amount)
@balance -= amount
end
end
This implementation, where the balance is updated during the method call
to credit or debit, means that we can be certain the balance will have been
updated by the time Cucumber checks the account balance in the final Then
step of our scenario.
Download support_code/18/features/cash_withdrawal.feature
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
Then $20 should be dispensed
And the balance of my account should be $80
When we change to our new architecture; however, the transactions will be
processed by a separate backend service. Because the tests and backend
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How to Synchronize
• 159
ATM
Transaction
Queue
Balance Store
Transaction
Processor
Figure 10—Enterprise messaging architecture
service are running in separate processes, it’s quite possible that Cucumber
will run the Then step before the transaction processor has finished its work.
If that happened, the test would fail even though the system is actually
working as expected: if only Cucumber had waited a few more moments, it
would have seen the right balance. This is what we call a flickering scenario,
as described in Chapter 6, When Cucumbers Go Bad, on page 85. How can
we tell when it’s safe to check the account balance?
Adding asynchronous components into a system introduces a degree of randomness, but for our tests to be reliable, we need to ensure that the behavior
is completely deterministic. To do that, we need to understand how we can
synchronize our tests with the system, so that we make our checks only when
the system is ready. In Growing Object-Oriented Software, Guided by Tests
[FP09], Steve Freeman and Nat Pryce identify two ways to synchronize your
tests with an asynchronous system: sampling and listening.
Synchronizing by Listening
Listening for events is the fastest and most reliable way to synchronize your
tests with an asynchronous system. For this technique to work, the system
under test has to be designed to fire events when certain things happen. The
tests subscribe to these events and can use them to create synchronization
points in the scenario.
For example, if the Transaction Processor were emitting BalanceUpdated events into
a publish-subscribe message channel, we could wait at the top of our Then
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Synchronizing with Delayed Job
In Ruby applications, Delayed Joba is a popular gem for running background tasks
asynchronously. We recommend working with Delayed Job by having a method in
your support layer like this:
module DelayedJobSupport
def process_all_jobs
Delayed::Worker.new.work_off(Delayed::Job.count)
if ENV['FAIL_FAST']
raise Delayed::Job.first.last_error if Delayed::Job.count > 0
end
end
end
World(DelayedJobSupport)
The first line of the method tells Delayed Job to process all of the jobs in its queue.
This is normally done by a background task in production, so by calling this code
from your step definitions, you’ll make sure they will wait here until the jobs are all
processed. We’re not actually using listening or sampling here; we’re bringing what
is normally an asynchronous component into our process, making it synchronous.
You’ll have to call this method yourself from your step definitions at the points when
you want to synchronize.
The last part of the method raises an error if any of the jobs have failed. We don’t
always want to do this—we might be running a scenario where the expected behavior
is for the job to fail—but it can be useful to have this available for debugging. Using
the environment variable like this allows us to switch to this debug mode easily:
$ cucumber features/background_jobs.feature FAIL_FAST=1
If you wanted to stay closer to how the code behaves in production and keep Delayed
Job running asynchronously, you’ll still need to synchronize. In this case, you could
use sampling to poll Delayed Job’s queue until it was empty.
a.
http://rubygems.org/gems/delayed_job
step until we heard that event. Once we’d received that event, we’d know it
was safe to proceed and check the balance. We would use a timeout to ensure
the tests didn’t wait forever if something was wrong with the system.
Using events like this involves a sophisticated coordination of your testing
and development efforts, but it results in fast tests because they don’t waste
any time waiting for the system: as soon as they’re notified of the right event,
they spring back into action and carry on.
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Synchronization by Sampling
When it isn’t possible to listen to events from the system, the next best option
is to repeatedly poll the system for the state change you’re expecting. If it
doesn’t appear within a certain timeout, you give up and fail the test.
Sampling can result in tests that are a little bit slower than listening, because
of the polling interval. The more often you poll the system for changes, the
quicker the tests can react and carry on when the system is working as
expected. If you poll too frequently, however, you could put excessive load on
the system.
Sampling is usually the pragmatic choice when you don’t have the option to
receive events from the system under test. In the rest of this chapter, we’ll
show you how to use sampling to make our tests work reliably with the new
architecture.
9.3
Implementing the New Architecture
So that we can show you what it’s like to have a flickering scenario, we’ll start
by changing the architecture underneath the same test code. We’ll demonstrate
the flickering scenario and, in a final flourish, fix it by changing the tests to
use sampling to synchronize with the system.
Driving Out the Interfaces
The Account class is where the ATM is going to interface with our new backend
services. As shown in Figure 10, Enterprise messaging architecture, on page
159, the two touch points are the TransactionQueue and the BalanceStore. Let’s design
the interfaces to those objects by changing our Account class to use two imaginary objects that can talk to these services:
Download message_queues/01/lib/nice_bank.rb
require_relative 'transaction_queue'
require_relative 'balance_store'
class Account
def initialize
@queue = TransactionQueue.new
@balance_store = BalanceStore.new
end
def balance
@balance_store.balance
end
def credit(amount)
@queue.write("+#{amount}")
end
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def debit(amount)
@queue.write("-#{amount}")
end
end
We’ve used Ruby 1.9’s require_relative at the top of the file, so we’re assuming
that the two new classes will be defined in files that sit in the same directory
as this one. Getting the balance is a simple matter of delegating to the BalanceStore. In a more realistic system, we’d need to tell the BalanceStore which account
we wanted the balance for, but in our simple example we’re dealing only with
a single account, so we don’t need to worry about that.
For debits and credits, we’re serializing the transaction as a string, using a
+ or - to indicate whether the amount is a credit or a debit, and then writing
it to the queue.
Building the TransactionQueue
Let’s build our transaction queue. We want to keep the technology really
simple for this example, so we’re going to use the file system as our message
store, with each message stored as a file in a messages directory. As a message
is read from the queue, we’ll delete the file. Here’s the code:
Download message_queues/01/lib/transaction_queue.rb
require 'fileutils'
class TransactionQueue
def self.clear
FileUtils.rm_rf('messages')
FileUtils.mkdir_p('messages')
end
def initialize
@next_id = 1
end
def write(transaction)
File.open("messages/#{@next_id}", 'w') { |f| f.puts(transaction) }
@next_id += 1
end
def read
next_message_file = Dir['messages/*'].first
return unless next_message_file
yield File.read(next_message_file)
FileUtils.rm_rf(next_message_file)
end
end
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This is fairly simple Ruby code, but it’s the most complicated we’ve had in
the book so far, so let’s run through how it works. First we have a class
method, TransactionQueue.clear, which we’ll use to ensure the queue is cleaned
up between scenarios. When we initialize the TransactionQueue, we create an
instance variable @next_id, which will be used to give each new message a
unique filename. When we’re asked to write a message, we create a new file
in the messages directory, write the contents of the message into the file, and
then increment @next_id ready for naming the next message’s file.
When we’re asked to read a message, we try to find a file in the messages directory. If the directory is empty, we just return from the method. If we do find
a message, we read it, yield the contents to the caller, and then delete the
message from the queue. If you’re new to Ruby, you might not know how yield
works, but try not to worry—it will become clear when you see how this code
is used. As always, for more information about programming in Ruby, we
recommend Everyday Scripting with Ruby [Mar07] or the classic Programming
Ruby: The Pragmatic Programmer’s Guide [TFH08].
We’ve put the TransactionQueue in its own file and required it from the main
lib/nice_bank.rb program. That’s because we need to use this library class both
from the ATM web server and from our TransactionProcessor. We’re going to do
the same thing with the BalanceStore, which is what we’ll build next.
Building the BalanceStore
The BalanceStore is a database where the latest account balance is stored. Again,
we want to keep the technology simple for this example, so we’ll use a very
simple kind of database: a text file on disk. Here’s the code:
Download message_queues/01/lib/balance_store.rb
require 'fileutils'
class BalanceStore
def balance
File.read('balance').to_i
end
def balance=(new_balance)
File.open('balance', 'w') { |f| f.puts(new_balance) }
end
end
We have two methods, one that reads the balance and another that sets it.
They both work with a file in the root of our project called balance. When it’s
asked to set the balance, the BalanceStore opens the balance file and writes the
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new balance into it. When asked for the balance, the BalanceStore reads the file
and converts the contents to a number. Simple!
Now that we’re persisting state to disk in our TransactionQueue and BalanceStore,
we need to be careful that we don’t leak any state out of our scenario. Even
though we have only a single scenario in our features at the moment, we need
to clean up each time it runs so that balances and messages don’t leak from
one test run into the next.
Adding Hooks to Reset State
We have two places where state will need to be cleaned up before our scenario
runs. We need to set the user’s account balance to zero, and we need to remove
any messages that have been left in the transaction queue. Add a file features/support/hooks.rb with the following code in it:
Download message_queues/01/features/support/hooks.rb
Before do
BalanceStore.new.balance = 0
TransactionQueue.clear
end
We’ve created a new instance of the BalanceStore directly so that we can tell it
to set the balance to zero. Then we use the TransactionQueue.clear method we
created earlier to empty any messages out of the transaction queue.
Let’s put the last piece in the puzzle by writing our TransactionProcessor.
Building the TransactionProcessor
The TransactionProcessor is a Ruby program that will run in the background, deep
in the bowels of our bank’s server room. Here’s the code:
Download message_queues/01/lib/transaction_processor.rb
require_relative 'transaction_queue'
require_relative 'balance_store'
transaction_queue = TransactionQueue.new
balance_store = BalanceStore.new
puts "transaction processor ready"
loop do
transaction_queue.read do |message|
sleep 1
transaction_amount = message.to_i
new_balance = balance_store.balance + transaction_amount
balance_store.balance = new_balance
end
end
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• 165
The program starts by creating an instance of the TransactionQueue and BalanceStore classes. It prints a message to the console to say it’s started up and then
enters a loop. The loop tries to read a message off the transaction queue. If
it finds one, it pauses for a second, calculates the new balance, and then
stores it on the BalanceStore. We’ve introduced the pause to demonstrate the
effects of working with an asynchronous component in our system: this delay
should mean the test will fail consistently because the backend will take so
long to update the balance that Cucumber will have already finished the
scenario.
That should complete the implementation of our new architecture. Now it’s
time to test it.
9.4
Fixing the Flickering Scenario
We’re almost ready to run our scenario again, but before we do, there’s one
thing we need to change in our tests. Right now, when we run cucumber, we’ll
rely on Capybara to control the web server part of our architecture, but we
need a way to start up the backend transaction processor too. To do that,
we’ll use a neat little gem called Service Manager.2
Installing and Configuring Service Manager
First we need to add service_manager to the Gemfile:
Download message_queues/01/Gemfile
source :rubygems
gem 'sinatra', '1.3.1'
gem 'service_manager', '0.6.2'
group
gem
gem
gem
gem
end
:development do
'rspec', '2.7.0'
'cucumber', '1.1.3'
'capybara', '1.1.2'
'launchy', '2.0.5'
Now run bundle install to install the new gem.
Service Manager will automatically start and stop multiple backend processes
when you ask it to, which takes away a lot of the pain of working with backend
services in your tests. We need to give Service Manager a bit of configuration
2.
http://rubygems.org/gems/service_manager. Sadly, at the time of writing, Service
Manager does not support Windows. See Building a Poor Man's Service Manager for
Windows, on page 166 for a workaround.
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Building a Poor Man’s Service Manager for Windows
At the time of writing, Service Manager does not work on Windows. If you’re using
Windows, you’ll need to ignore those parts of this chapter, but you’ll still need a way
to start up the backend service before the tests run and stop it again at the end.
We’re going to show you another way to control processes that’s a little bit more lowlevel than Service Manager but should work on Windows.
The first thing you’ll need is to add another gem, childprocess, to your Gemfile:
gem 'childprocess'
In your features/support directory, add a script to start and stop the backend service:
Download message_queues/03-win32/features/support/services.rb
require 'childprocess'
process = ChildProcess.build('ruby', 'lib/transaction_processor.rb')
process.start
at_exit { process.stop }
This illustrates the basics of using ChildProcess to control an external process. We
tell ChildProcess the program we want to run and tell it to start. We use Ruby’s
at_exit hook to tell ChildProcess to stop the transaction processor when the Cucumber
tests are all done and Cucumber is exiting.
There is one slight flaw in this technique. Unlike Service Manager, we don’t wait for
the transaction processor to confirm that it’s started by looking for the printed ready
statement in the output. This is because Windows can sometimes buffer process
output, so we could be waiting forever for anything to appear! So, it’s possible that
we could go ahead and start running our tests before the transaction processor was
ready to work. This is unlikely because the transaction processor is pretty lightweight,
but you might need to consider this in your own applications and work around it by
sending a signal from the backend process, like touching a file, for example.
so it knows what to do. You’ll need to create a new config directory and add
this file:
Download message_queues/01/config/services.rb
require "service_manager"
ServiceManager.define_service "transaction_processor" do |s|
s.start_cmd = "ruby lib/transaction_processor.rb"
s.loaded_cue = /ready/
s.cwd = Dir.pwd
s.pid_file = 'transaction_processor.pid'
end
This configuration tells Service Manager what command to run in order to
start our backend service. It also gives it a string to watch out for (in this case
ready) so that it knows when the service has started up. We told it the working
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directory to use, and we gave it the name of a process identifier (PID) file
where Service Manager can keep track of the identity of the running service.
When Cucumber has finished, Service Manager will use the PID to shut down
the backend service for us automatically.
Now we just need to tell Service Manager to start up when our tests run. Add
a file features/support/services.rb to the project:
Download message_queues/01/features/support/services.rb
require "service_manager"
ServiceManager.start
Now, when Cucumber runs, that file will load and tell Service Manager to get
started. It will check its configuration file and start up our backend transaction
processor.
Finally, we’re ready to run our scenario again.
Investigating the Flickering
Our tests are all hooked up to our new architecture, so we’re ready to run
them and do some investigation into our flickering tests. Run Cucumber and
give it a try:
Starting transaction_processor in ~/message_queues/01 with
'ruby lib/transaction_processor.rb'
transaction processor ready
Server transaction_processor (94557) is up.
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
Then $20 should be dispensed
And the balance of my account should be $80
expected: 80
got: 0
(compared using ==)
(RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/account_steps.rb:6
features/cash_withdrawal.feature:6
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
4 steps (1 failed, 3 passed)
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0m0.602s
Shutting down transaction_processor (94557)
Server transaction_processor (94557) is shut down
You’ll notice the extra output from Service Manager at the top and bottom of
the output, telling us that it’s started up the backend service for us and
stopped it again. The test has failed, though, and the cause is because of
timing: Cucumber looked in the balance store and found that the balance
was zero when it expected it to be 80. That’s because we introduced the onesecond pause into the transaction processor, meaning it loses its race with
Cucumber every time. It didn’t get chance to update the balance before
Cucumber checked it and failed the scenario.
Let’s swap things around and give the handicap to Cucumber instead of the
transaction processor. Remove the sleep 1 line from the transaction processor
and put it into Cucumber’s Then step instead. Your files should now look like
this:
Download message_queues/02/lib/transaction_processor.rb
require_relative 'transaction_queue'
require_relative 'balance_store'
transaction_queue = TransactionQueue.new
balance_store = BalanceStore.new
puts "transaction processor ready"
loop do
transaction_queue.read do |message|
transaction_amount = message.to_i
new_balance = balance_store.balance + transaction_amount
balance_store.balance = new_balance
end
end
Download message_queues/02/features/step_definitions/account_steps.rb
Given /^my account has been credited with (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
my_account.credit(amount)
end
➤
Then /^the balance of my account should be (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
sleep 1
my_account.balance.should eq(amount)
end
We’ve moved the sleeps around so that Cucumber loses the race every time,
meaning the backend processor will always finish first. Run cucumber now,
and you should see the scenario pass.
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Catching Exceptions from External Services
When you run the code you’re testing in the same Ruby process as Cucumber is
running in, any exception raised by the code being tested will be raised right up and
displayed by Cucumber in the console. When the error occurs in an out-of-process
component, however, Cucumber can’t see the error and won’t report it to you. This
can be really confusing because your test fails but you have no idea why.
If you use Service Manager to orchestrate your backend services, and those services
report their errors to their own console output, then Service Manager will print them
into Cucumber’s console output too. Otherwise, an easy route is to write the errors
to a log file and then check that log file from your Cucumber tests, perhaps in an After
block.
This illustrates just how fragile tests for asynchronous systems can be to
timing issues. We could just leave it like this, but for one thing, it’s unnecessarily slow. Even though the transaction processor takes much less than a
second to update the balance, our step will always pause for the full second.
Also, if we make a change in the future to the transaction processor that
means it takes more than one second, the test will start to fail again.
Try This
To experience the true randomness of a flickering scenario, remove both sleeps
and run cucumber several times over:
$ ruby -e "30.times { system 'cucumber -f progress' }"
You should find that, from that sample of several runs, you’ll get a mixture
of passing and failing results.
Using Sampling to Fix the Flickering
Now that you’ve seen a flickering test at firsthand, let’s fix it properly. What
we need to do is change the way our Then step behaves so that rather than
simply checking the balance once, it checks it repeatedly until it reaches the
value we expect.
Let’s imagine we have a method eventually in our World that will keep trying to
run a block of code until either it stops raising an error or it reaches a time
limit. Here’s how we could use it:
Download message_queues/03/features/step_definitions/account_steps.rb
Then /^the balance of my account should be (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
eventually { my_account.balance.should eq(amount) }
end
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Joe asks:
Should I Show Synchronization Points in
My Features?
In this chapter, we’ve used the eventually method to introduce an implicit synchronization point into our scenario without changing the Gherkin itself. This means that the
fact that the behavior is actually asynchronous is hidden from anyone reading the
scenario. In many situations, asynchronous behavior is a technical detail that doesn’t
need to be surfaced in the features, but sometimes it’s something your readers will
want to see in the scenarios.
The key question is whether the nontechnical stakeholders on your project care about
the asynchronous behavior of the system. Ask them. Perhaps they would prefer to
read this:
Given my account has been credited with $100
When I withdraw $20
Then $20 should be dispensed
➤ When I wait for all the transactions to be processed
Then the balance of my account should be $80
Remember, writing Cucumber features is about communicating the behavior of the
system. The right amount of detail will be different for every team and every project,
so ask your team what they think.
Because the should assertion will raise an error if the balance isn’t the expected
amount, eventually will keep trying until the assertion passes or the timeout is
reached. We can implement this method by adding a new module of code to
our support layer:
Download message_queues/03/features/support/async_support.rb
module AsyncSupport
def eventually
timeout = 2
polling_interval = 0.1
time_limit = Time.now + timeout
loop do
begin
yield
rescue Exception => error
end
return if error.nil?
raise error if Time.now >= time_limit
sleep polling_interval
end
end
end
World(AsyncSupport)
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What We Just Learned
• 171
This code uses Ruby’s begin..rescue structure to run the block of code passed
to the method and catch any error. If there was no error, we return from the
method, meaning the step can carry on successfully. Remember that Cucumber will assume the step has passed unless it raises an error. If there was an
error and the time limit has been reached, we raise the error so the step will
fail. Finally, we take a little sleep to give the system a chance to do other
things before we go around the loop again.
To really test this, put the sleep 1 line back into the transaction processor and
run cucumber. You should see the scenario pause for a second as our eventually
method waits for the system to update the balance and then pass.
Try This
To satisfy yourself that our new method would fail if there were a problem
with the transaction processor, try putting the sleep in the transaction processor up to three seconds. Because the timeout in our eventually is only two
seconds, the scenario should fail.
Testing That Nothing Happens
One last thing to consider: suppose you have a scenario where you credit the
account with $100, withdraw $100, and then check that the balance is zero.
If the test passes, how can you be sure that the tests have seen the balance
after the transactions have been processed? It’s possible that the transaction
processor might not have started processing the transactions or even failed
altogether. You’d never know, because the outcome you’re looking for to indicate success looks just like the state of the system when you started the
scenario.
This kind of problem illustrates the disadvantage of using sampling to synchronize. If you could listen for events from the Transaction Processor, you
could wait until you were sure it had finished its work before checking the
balance. Using sampling, you’re still left with a potential timing problem.
In these circumstances, you need to introduce an intermediate synchronization
point into the scenario to make sure that the system has moved away from
the default state. After crediting the account with $100, you need to wait for
that credit to have an effect, sampling for the changed balance, before proceeding with the next step.
9.5
What We Just Learned
When you add asynchronous behavior to a system, you need to make a concerted effort to tame the random effects that it can have on your tests. Build
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Matt says:
Other Asynchronous Assertions
There are alternatives to rolling your own eventually as we’ve done in this chapter. Josh
Chisholm’s Anticipatea gem gives you a fluent interface for expressing the same kind
of assertion:
trying_every(0.1).seconds.failing_after(20).tries do
my_account.balance.should eq(amount)
end
The eventually itself has been added into the Wrongb assertion library.
a.
b.
http://rubygems.org/gems/anticipate
http://rubygems.org/gems/wrong
your tests with a knowledge of how the system works and introduce synchronization points where timing issues are likely to arise.
Using sleeps in your steps is not a good way to tackle these timing issues,
because it makes your tests slow and doesn’t solve the reliability problem: if
the system changes and becomes slower, your sleep may not be long enough
and the test will start to break again. The best solution is to listen for events
broadcast by the system and pause at the appropriate points in the scenario
until those events have been received. That way, you minimize the amount
of time the tests waste waiting for the system.
The next best solution is to use sampling to repeatedly poll the system,
looking for an expected change of state. This approach works in most circumstances, but you need to take care, especially when the outcome you’re
looking for at the end of the scenario looks just the same as at an earlier time
in the scenario.
Try This
Do some more experiments with this code, adding sleeps into the code in
different places to make sure you understand how the timing issues affect
the reliability of the scenario. Try to draw a sequence diagram5 of what’s going
on as the scenario runs.
Think about your own system. Are there any places where there is asynchronous behavior? How do you work around that in the tests at the moment?
Could you improve on that using what you’ve learned in this chapter?
5.
http://en.wikipedia.org/wiki/Sequence_diagram
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CHAPTER 10
Databases
Back in Chapter 6, When Cucumbers Go Bad, on page 85 we described the
risks associated with leaky scenarios, where data left behind by one scenario
affects the results of the next. In this chapter we’re going to illustrate this
problem with an example, and we’ll describe the two methods for dealing with
it, along with their advantages and disadvantages.
For this final installment of the worked example, we’re going to introduce a
relational database into our ATM system. Almost every system you’ll write
Cucumber tests for will have a database of some kind, and it helps to know
how to talk to it directly from your test code. You can use ActiveRecord to
connect to almost any kind of database and set up or inspect its data from
your tests. We’re going to show you how to use the ActiveRecord1 gem to
connect to existing databases from just a few lines of Ruby code.
Right now, our file-based database can only store the balance of a single
customer’s account. Let’s introduce the capacity to store the balance for
several different accounts, using a database table to store each customer’s
account balance in a separate row.
We’ll use an sqlite32 database, although the choice of database is not all that
important to this example. That’s because we’ll be talking to it through
ActiveRecord, which provides the same consistent interface to every relational
database that it talks to.3 It’s a useful library for testers to know about, so
we’ll start with an introduction to that library before we plug it into our
example.
1.
2.
3.
http://rubygems.org/gems/activerecord
http://www.sqlite.org/
At the time of this writing, ActiveRecord has drivers for MySQL, PostgreSQL, SQLite,
SQL Server, Sybase, DB2, and Oracle databases.
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10.1 Introducing ActiveRecord
ActiveRecord was born in the Ruby on Rails framework, but it’s easy to use
it from stand-alone Ruby code to talk to any existing database. For example,
if we had an accounts table with the following data in it:
id
number
balance
1
1765
80
2
2214
250
then we could query that database table using the following Ruby code:
>> account = Account.find_by_number(2214)
>> puts account.balance
=> 250
Similarly, to add a new row to the table, we could do this:
new_account = Account.create!(:number => 1234, :amount => 0)
We still need to define this Account class, but the clever thing is, we don’t need
to define the database columns in the code. Here’s how the class is defined:
class Account < ActiveRecord::Base
end
That’s it! ActiveRecord examines the database schema and sprinkles a little
bit of Ruby’s metaprogramming magic to dynamically extend the Account class
with attribute accessor methods, each representing a column in the database
table. It even creates special class methods like find_by_number for searching
for rows by a particular field. All we have to do is inherit from ActiveRecord::Base,
and ActiveRecord does the rest.
How does it know which table to look at? ActiveRecord espouses a principle
of convention over configuration. This means that the expected name for the
database table represented by the Account ActiveRecord class is accounts; if the
table were named widgets, we’d call the class Widget. As long as we stick to those
conventions, we get a lot of very useful behavior for very little code.
Managing Schema Changes with Migrations
ActiveRecord also provides a mechanism for dealing with changes to your
database schema, which is great when you’re developing a database. Each
incremental change to the schema is defined in a migration script. Each
migration has a unique version number, and ActiveRecord stores these version
numbers in a special table (schema_migrations) as they are applied to the database,
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Tweaking ActiveRecord for Nonconventional Databases
ActiveRecord’s default conventions are great if you’re building a database from scratch,
but what if you’re working with a legacy system? If your database doesn’t fit ActiveRecords’ conventions, you can override the defaults like this:
class Account < ActiveRecord::Base
set_table_name 'tblAccount'
alias_attribute :number, 'intNumber'
alias_attribute :balance, 'moneyBalance'
end
The set_table_name method allows you to tell ActiveRecord the name of the table to use,
while alias_attribute tells ActiveRecord you want to map the ugly name of the database
column to a more conventional method name on the Ruby class.
meaning it can always tell which migrations need to be applied to bring a
schema up-to-date. For more about migrations, check the documentation.4
Now you have some grounding in ActiveRecord, let’s get our hands dirty and
start adding it to our banking system.
10.2 Refactoring to Use a Database
In our current system, the balance of the single account is stored in a file
and read and written by the BalanceStore class. In our new design, we will make
the Account responsible for reading the balance straight out of a database
instead. It’s refactoring time again!
We’ll start by moving the Account class into its own lib/account.rb file and make
it an ActiveRecord class:
Download databases/00/lib/account.rb
require 'active_record'
ActiveRecord::Base.establish_connection(:adapter => 'sqlite3',
:database => 'db/bank.db')
ActiveRecord::Migrator.migrate("db/migrate/")
class Account < ActiveRecord::Base
validates_uniqueness_of :number
def queue
@queue ||= TransactionQueue.new
end
def credit(amount)
queue.write("+#{amount},#{number}")
end
4.
http://api.rubyonrails.org/classes/ActiveRecord/Migration.html
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def debit(amount)
queue.write("-#{amount},#{number}")
end
end
At the top of the file we set up ActiveRecord to use a SQLite database in
db/bank.db. We are also telling ActiveRecord to run migrations in the db/migrate/
directory. This will force it to update our database schema, if necessary, as
soon as we load this file. Then we create our Account, inheriting from ActiveRecord::Base so that it will act on the accounts table we’re about to create.
We’ll create an accounts table shortly with three columns:
id
The primary key, which is generated automatically by ActiveRecord.
number
The account number, which serves as a secondary key. This has
to be unique. We’ve used ActiveRecord’s validates_uniqueness_of method
within our Account class to enforce this.
balance
The current balance of the account.
ActiveRecord will make all three fields available as attributes of each Account
instance. This is why we ’ve removed the :balance field that we had before we
refactored the class. We’ve also changed the credit and debit methods to write
out the account number as well as the amount so that the TransactionProcessor can
know what account a message refers to.
Let’s set up a database migration that will create the accounts table if it doesn’t
exist. We’ll store the migration script in db/migrate/01_create_accounts.rb:
Download databases/00/db/migrate/01_create_accounts.rb
class CreateAccounts < ActiveRecord::Migration
def change
create_table :accounts do |t|
t.string :number
t.integer :balance
end
end
end
Now that we have an Account that knows how to persist itself along with the
balance it’s time to get rid of the BalanceStore class, so we will simply delete the
lib/balance_store.rb file. We also need to modify features/support/hooks.rb, which no
longer needs to reference it:
Download databases/00/features/support/hooks.rb
Before do
TransactionQueue.clear
end
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The next step is to update our require_relative statements. The top of our
lib/nice_bank.rb now looks like this:
Download databases/00/lib/nice_bank.rb
require_relative 'transaction_queue'
require_relative 'account'
class Teller
And here is lib/transaction_processor.rb:
Download databases/00/lib/transaction_processor.rb
require_relative 'transaction_queue'
require_relative 'account'
transaction_queue = TransactionQueue.new
puts "transaction processor ready"
Before we run Cucumber again, we’ll add the activerecord and sqlite3 gems to
our Gemfile:
Download databases/00/Gemfile
source :rubygems
gem
gem
➤ gem
➤ gem
'sinatra', '1.3.1'
'service_manager', '0.6.2'
'activerecord', '3.1.3'
'sqlite3', '1.3.5'
group
gem
gem
gem
gem
end
:development do
'rspec', '2.7.0'
'cucumber', '1.1.3'
'capybara', '1.1.2'
'launchy', '2.0.5'
Now let’s run bundle install followed by cucumber:
== CreateAccounts: migrating =================================================
-- create_table(:accounts)
-> 0.0010s
== CreateAccounts: migrated (0.0011s) ========================================
Starting transaction_processor in ~/message_queues/01 with
'ruby lib/transaction_processor.rb'
transaction processor ready
Server transaction_processor (94557) is up.
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
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When I withdraw $20
Then $20 should be dispensed
lib/transaction_processor.rb:13:in `block (2 levels) in <main>':
undefined local variable or method `balance_store' for main:Object (NameError)
from ~/databases/00/lib/transaction_queue.rb:21:in `read'
from lib/transaction_processor.rb:10:in `block in <main>'
from lib/transaction_processor.rb:9:in `loop'
from lib/transaction_processor.rb:9:in `<main>'
And the balance of my account should be $80
expected: 80
got: nil
(compared using ==)
(RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/account_steps.rb:7
./features/support/async_support.rb:8
./features/support/async_support.rb:6
./features/support/async_support.rb:6
./features/step_definitions/account_steps.rb:7
features/cash_withdrawal.feature:6
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
4 steps (1 failed, 3 passed)
0m2.284s
Shutting down transaction_processor (94557)
Server transaction_processor (94557) is shut down
The first thing we see is that the database is automatically migrated—the
accounts table is created. This technique of letting the application automatically
migrate the database when it starts is a handy trick. But then we get a failure
further down.
It looks like we have some more work to do. Not to worry—Cucumber tells us
exactly what we need to fix. We no longer have a balance_store, so we need to
load the balance in a different way.
10.3 Reading and Writing to the Database
When we modified the Account earlier, we made it write out each transaction
message as amount,account_number. The TransactionProcessor needs the account_number
to find an account in the database and update its balance:
Download databases/01/lib/transaction_processor.rb
require_relative 'transaction_queue'
require_relative 'account'
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➤
➤
➤
➤
➤
• 179
transaction_queue = TransactionQueue.new
puts "transaction processor ready"
loop do
transaction_queue.read do |message|
sleep 1
transaction_amount, number = message.split(/,/)
account = Account.find_by_number!(number.strip)
new_balance = account.balance + transaction_amount.to_i
account.balance = new_balance
account.save
end
end
However, looking at the message files in the messages directory, we see that
the account numbers are missing. That’s because we haven’t assigned an
account number anywhere! Let’s go back to the code where we instantiate an
Account and make it assign a number, and while we’re at it, let’s save it to the
database using ActiveRecord’s create! method:
Download databases/02/features/support/world_extensions.rb
def my_account
@my_account ||= Account.create!(:number => "test", :balance => 0)
end
The step that failed is now passing, and we’re left with a last failing step:
Starting transaction_processor in ~/message_queues/01 with
'ruby lib/transaction_processor.rb'
transaction processor ready
Server transaction_processor (94557) is up.
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
Then $20 should be dispensed
~/.rvm/gems/ruby-1.9.3-p0@hwcuc/gems/activerecord-3.1.3/
lib/active_record/relation/finder_methods.rb:266:in `find_by_attributes':
Couldn't find Account with number = (ActiveRecord::RecordNotFound)
from ~/.rvm/gems/ruby-1.9.3-p0@hwcuc/gems/activerecord-3.1.3/
lib/active_record/base.rb:1063:in `method_missing'
from lib/transaction_processor.rb:12:in `block (2 levels) in <main>'
from ~/databases/02/lib/transaction_queue.rb:21:in `read'
from lib/transaction_processor.rb:8:in `block in <main>'
from lib/transaction_processor.rb:7:in `loop'
from lib/transaction_processor.rb:7:in `<main>'
And the balance of my account should be $80
expected: 80
got: 0
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(compared using ==)
(RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/account_steps.rb:7
./features/support/async_support.rb:8
./features/support/async_support.rb:6
./features/support/async_support.rb:6
./features/step_definitions/account_steps.rb:7
features/cash_withdrawal.feature:6
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
4 steps (1 failed, 3 passed)
0m2.389s
Shutting down transaction_processor (94557)
Server transaction_processor (94557) is shut down
We expected the balance to be $80, but it looks like it’s still $0. Where did
the money go? Let’s look in the database.
$ sqlite3 db/bank.db
sqlite> select * from accounts;
1|test|80
sqlite> .quit
Phew! The money is safe in our account. It turns out the step failed because
we are still looking at the original instance of the account record—stored in
@my_account—from when we created it with a zero balance. Even though the
underlying database row has been modified by the TransactionProcessor, ActiveRecord doesn’t know that the record we have is out-of-date, so we need to tell
it to reload the record from the database:
Download databases/03/features/step_definitions/account_steps.rb
Then /^the balance of my account should be (#{CAPTURE_CASH_AMOUNT})$/ do |amount|
eventually { my_account.reload.balance.should eq(amount) }
end
Let’s run the scenario again:
Starting transaction_processor in ~/message_queues/01 with
'ruby lib/transaction_processor.rb'
transaction processor ready
Server transaction_processor (94557) is up.
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
Validation failed: Number has already been taken
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Cleaning the Database with Transactions
• 181
(ActiveRecord::RecordInvalid)
./features/support/world_extensions.rb:20
./features/step_definitions/account_steps.rb:2
features/cash_withdrawal.feature:3
When I withdraw $20
Then $20 should be dispensed
And the balance of my account should be $80
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
4 steps (1 failed, 3 skipped)
0m0.077s
Shutting down transaction_processor (94557)
Server transaction_processor (94557) is shut down
This time the first step in our scenario, which ran perfectly fine the last time
we run the scenario, has failed. We have stumbled upon one of the most
common problems of automated tests for a system using a database. The
previous test run left data in the database, and running it again makes it fail.
We can’t create an account because the Account number has to be unique, and
a row for that Account was left behind by the previous test run. We have a leaky
scenario!
The good thing about common problems is that there often is a common
solution. We have to make sure each scenario starts with a clean database.
There are two strategies to achieve this—transaction and truncation. We’ll
explore both, starting with transactions.
10.4 Cleaning the Database with Transactions
This is a clever approach that uses the database’s transaction support in a
somewhat unusual way. Before the scenario starts, we start a new database
transaction in a Before hook. Then, our step definitions and application insert
and modify data in the database. However, since this is happening in an
uncommitted transaction, nothing actually gets changed in the database
until the transaction is committed. Then, when the scenario is over (in an After
hook), we do the opposite. We roll the transaction back! All the data that was
modified during the scenario gets lost, and the database is back in its original
state. You can see how this works in Figure 11, Database transactions, on
page 182.
This is actually what we want. It means that the next scenario that comes
along starts with a blank slate, and we don’t need to worry about leftovers
from the previous scenario.
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• Chapter 10. Databases
Cucumber
Application
Database
begin txn
insert data
do something
read data
rollback txn
delete all
inserted data
Figure 11—Database transactions
Unfortunately, the transaction approach doesn’t work for our application.
Understanding why this doesn’t work is essential, so we are going to try it
anyway. Seeing it fail and understanding why will save you hours of problem
solving in the future. It will also help you understand when to use transactions
and when not to use them.
Our previous run would have left a row in the accounts table, so let’s remove
that before we try to run with transactions:
$ sqlite3 db/bank.db
sqlite> delete from accounts;
sqlite> .quit
Now that we have a clean database, let’s configure Cucumber to begin and
roll back a transaction. DatabaseCleaner5 is a Ruby gem that provides an
easy way to ensure the database is in a clean state before each scenario starts.
Let’s add it to our Gemfile:
5.
DatabaseCleaner (https://github.com/bmabey/database_cleaner) was written by Ben
Mabey, who was also one of the first contributors to Cucumber.
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• 183
Download databases/04/Gemfile
source :rubygems
gem
gem
gem
gem
'sinatra', '1.3.1'
'service_manager', '0.6.2'
'activerecord', '3.1.3'
'sqlite3', '1.3.5'
group
gem
gem
gem
gem
➤
gem
end
:development do
'rspec', '2.7.0'
'cucumber', '1.1.3'
'capybara', '1.1.2'
'launchy', '2.0.5'
'database_cleaner', '0.7.0'
Now we have to define a Before hook that starts a transaction and an After hook
that rolls it back. Add the following to features/support/database.rb:
Download databases/04/features/support/database.rb
require 'database_cleaner'
DatabaseCleaner.strategy = :transaction
Before do
DatabaseCleaner.start
end
After do
DatabaseCleaner.clean
end
That’s all you need. In transaction mode, DatabaseCleaner.start opens a transaction, and DatabaseCleaner.clean rolls it back. Let’s see how that works:
Starting transaction_processor in ~/message_queues/01 with
'ruby lib/transaction_processor.rb'
transaction processor ready
Server transaction_processor (94557) is up.
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
Then $20 should be dispensed
~/.rvm/gems/ruby-1.9.3-p0@hwcuc/gems/activerecord-3.1.3/
lib/active_record/relation/finder_methods.rb:266:in `find_by_attributes':
Couldn't find Account with number = test (ActiveRecord::RecordNotFound)
from ~/.rvm/gems/ruby-1.9.3-p0@hwcuc/gems/activerecord-3.1.3/
lib/active_record/base.rb:1063:in `method_missing'
from lib/transaction_processor.rb:12:in `block (2 levels) in <main>'
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from ~/databases/04/lib/transaction_queue.rb:21:in `read'
from lib/transaction_processor.rb:8:in `block in <main>'
from lib/transaction_processor.rb:7:in `loop'
from lib/transaction_processor.rb:7:in `<main>'
And the balance of my account should be $80
expected: 80
got: 0
(compared using ==)
(RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/account_steps.rb:7
./features/support/async_support.rb:8
./features/support/async_support.rb:6
./features/support/async_support.rb:6
./features/step_definitions/account_steps.rb:7
features/cash_withdrawal.feature:6
Failing Scenarios:
cucumber features/cash_withdrawal.feature:2
1 scenario (1 failed)
4 steps (1 failed, 3 passed)
0m2.380s
Shutting down transaction_processor (94557)
Server transaction_processor (94557) is shut down
We told you it wasn’t going to work. It’s time to find out why. The TransactionProcessor couldn’t find the account we created in our first step. It throws an
exception, and our scenario fails. Why can’t the TransactionProcessor find the
account?
One of the properties of database transactions is that they are isolated. This
means that whatever database activity happens inside a transaction cannot
be seen by any other database connections. Don’t forget that we have two
database connections.
The first database connection is made by the process that runs Cucumber.
Cucumber begins a database transaction and creates an account.
The second database connection is made by the TransactionProcessor, which is
started in a separate process by ServiceManager. The TransactionProcessor pops
credit and debit messages off a queue, looks up accounts, and updates the
balance. However, since the database transaction that Cucumber started
hasn’t been committed, the TransactionProcessor can’t see the account we created
in or first step.
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Cleaning the Database with Truncation
• 185
Aslak says:
Browser Testing and Databases
The problem with transactional cleaning and multiple database connections often
occurs when we test web applications. This happens when the web application has
a different database connection than Cucumber. The problem typically manifests itself
in two situations:
• Cucumber inserts some data, but it isn’t displayed in the browser.
• A browser action causes some data to be inserted, but Cucumber can’t see it.
If this happens, you need to make sure you are not starting a transaction anywhere.
You have to use the truncation cleaning strategy instead. If you’re logging your
database calls, reading the logs can be very useful when diagnosing a problem like
this.
In Chapter 15, Using Capybara to Test Ajax Web Applications, on page 245, you will
learn how to drive a browser from Cucumber. Capybara actually runs the web server
in a separate thread within the same process, so you might think Cucumber and the
web server share the same database connection. In fact, they don’t—each thread also
gets its own database connection, which means transactional cleaning won’t work.
It obscures data from the other connection.
Cucumber-Rails allows you to override this behavior in features/support/env.rb so that
the Cucumber thread shares the connection with the web server. This means you
can use the faster transaction cleaning strategy. Be warned that this works only on
some databases. It may cause intermittent unexpected results on others!
Of course, we could have committed the transaction after creating the account,
but that would defeat our goal of rolling back to get a clean database when
the scenario is done. We can’t roll back a committed transaction. The rule is
simple: when the application has a different database connection than
Cucumber, we cannot use transactions to clean the database. We have to
use the other strategy instead: truncation.
10.5 Cleaning the Database with Truncation
Truncating the database before each scenario is a brute-force technique, and
the main drawback is that it’s generally slower than rolling back a transaction.
This is why the transactional approach is generally preferable if you can get
away with it. The advantage of truncation that it’s a cleaning strategy that
works reliably when we have more than one database connection, since no
transactions are used. Let’s modify our cleaning strategy and see how it
compares. This is a simple change in our database.rb file:
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Download databases/05/features/support/database.rb
require 'database_cleaner'
DatabaseCleaner.strategy = :truncation
Before do
DatabaseCleaner.clean
end
Notice how we removed the After hook and made the Before hook call DatabaseCleaner.clean instead. In truncation mode, DatabaseCleaner.start does nothing, and
DatabaseCleaner.clean truncates all tables. In other words, it deletes all rows.
Running Cucumber again makes the scenario pass again:
Starting transaction_processor in ~/message_queues/01 with
'ruby lib/transaction_processor.rb'
transaction processor ready
Server transaction_processor (94557) is up.
Feature: Cash Withdrawal
Scenario: Successful withdrawal from an account in credit
Given my account has been credited with $100
When I withdraw $20
Then $20 should be dispensed
And the balance of my account should be $80
1 scenario (1 passed)
4 steps (4 passed)
0m2.207s
Shutting down transaction_processor (94557)
Server transaction_processor (94557) is shut down
That brings us to the end of the worked example. What follows in the next
part are a series of recipes for using Cucumber in the wild. Good luck out
there!
10.6 What We Just Learned
Testing applications that use databases can be difficult. You have to make
sure each scenario starts with a clean slate, but cleaning the slate can have
its own pitfalls. In this chapter, we learned about the benefits and drawbacks
of two strategies—transaction and truncation. To sum it up:
• ActiveRecord is a useful library for quickly connecting to SQL databases.
• Resetting state between scenarios is vital; otherwise, you get weird failures.
• Transaction-based cleaning is preferred because it is fast, but it works
only when there is one single-threaded process.
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• 187
Joe asks:
Why Not Truncate the Database in an After Hook?
Truncating the database in an After hook usually works just as well as doing it in a
Before hook, but there is a subtle difference.
First, if the process gets killed before it has time to clean up in the After hook, it might
cause the next test run to fail.
Second, when a scenario fails it might not be evident why it failed, and having the
ability to peek inside the database as a post-mortem often helps us understand why
a scenario is failing.
As you will also see in Isolating Scenarios, on page 285, this post-mortem technique
can be used in other situations as well.
• Truncation-based cleaning is a slower, brute-force technique that works
in multiprocess and multithreaded environments.
Try This
Find an existing database, perhaps somewhere on your network at work, and
see if you can connect ActiveRecord to it. It should only take you a few lines
of Ruby code to set up an ActiveRecord::Base subclass that can talk to one of the
tables in the schema. Read up on ActiveRecord’s API documentation6 and try
running some queries against the database. See how easy it is to use Ruby
to talk to any database!
6.
http://api.rubyonrails.org/classes/ActiveRecord/Base.html
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Part III
Cucumber Applied
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CHAPTER 11
The Cucumber Command-Line Interface
Cucumber can be used to test almost any computer system. In this final part
of the book, we’re going to give you a set of recipes that you can pick and
choose from depending on your circumstances. Most of those recipes are
technical: you’ll find guidance on testing web services, command-line programs, and Ajax-heavy websites, but there’s also a chapter about testing
legacy systems that doesn’t contain much code at all. We’ll start by giving
you an in-depth tour of Cucumber’s user interface: the command line.
We have done our best to make Cucumber work out of the box without complex configuration. It doesn’t require you to provide a configuration file or
pass a lot of complex command-line options to work. However, there are times
when we want to tweak how Cucumber behaves.
Sometimes the default output can be too verbose, or perhaps we need it in a
format that is easier to share with others. We might want to run just a subset
of scenarios or perhaps organize the location of our Gherkin features and
step definitions a little differently.
In this chapter, we are going to take a closer look at what command-line
options Cucumber has to offer and how they can help you achieve some of
these things.
11.1 Cucumber’s Command-Line Options
Let’s start by taking a look at the command-line options. Like most commandline tools, Cucumber provides a --help option. The following is a shortened
version of what that would print:
$ cucumber --help
-r, --require LIBRARY|DIR
--i18n LANG
Require files before executing the features.
List keywords for in a particular language.
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• Chapter 11. The Cucumber Command-Line Interface
-f, --format FORMAT
-o, --out [FILE|DIR]
-t, --tags TAG_EXPRESSION
-n, --name NAME
-e, --exclude PATTERN
-p, --profile PROFILE
-P, --no-profile
-c, --[no-]color
-d, --dry-run
-a, --autoformat DIR
-m, --no-multiline
-s, --no-source
-i,
-q,
-b,
-S,
-w,
-v,
-g,
-l,
--no-snippets
--quiet
--backtrace
--strict
--wip
--verbose
--guess
--lines LINES
-x, --expand
--drb
--port PORT
--version
-h, --help
Run with "--i18n help" to see all languages.
How to format features (Default: pretty).
Write output to a file/directory instead of
STDOUT.
Only execute the features or scenarios with
tags matching TAG_EXPRESSION.
Only execute the feature elements which match
part of the given name.
Don't run feature files or require ruby files
matching PATTERN
Pull command line arguments from cucumber.yml.
Disables all profile loading to avoid using
the 'default' profile.
Whether or not to use ANSI color in the output.
Invokes formatters without executing the steps.
Reformats (pretty prints) feature files and
writes them to DIR.
Don't print multiline strings and tables under
steps.
Don't print the file and line of the step
definition with the steps.
Don't print snippets for pending steps.
Alias for --no-snippets --no-source.
Show full backtrace for all errors.
Fail if there are any undefined or pending steps.
Fail if there are any passing scenarios.
Show the files and features loaded.
Guess best match for Ambiguous steps.
Run given line numbers. Equivalent to FILE:LINE
syntax
Expand Scenario Outline Tables in output.
Run features against a DRb server. (i.e. with
the spork gem)
Specify DRb port. Ignored without --drb
Show version.
You're looking at it.
That’s a lot of options, and it may not be obvious when each one of them is
useful. Let’s look at some situations when you would use some of them.
11.2 Running a Subset of Scenarios
As the number of feature and scenarios grows, we’ll frequently run into situations where we want to run only a single (or maybe a couple) of scenarios
to get faster feedback. This can be if we are working on a new scenario or if
we have broken an existing one. Let’s take a closer look at how this works.
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• 193
Filtering with Tag Expressions
The simplest way to use the --tags option is to give it a single tag to run, for
example:
$ cucumber --tags @focus
This would cause Cucumber to run just the scenarios tagged with @focus. It’s
quite common to temporarily tag a scenario or feature with a unique tag like
this to filter what to run.
In some situations, we may want a little more control over the tag filtering.
Imagine that we have made some changes to a piece of our application that
sends out emails. What if we want to run all scenarios tagged with @focus or
@email? Here is how:
$ cucumber --tags @focus,@email
The comma is interpreted as a logical OR statement. It’s not uncommon to
have scenarios that run fast and others that run slowly. If we have tagged
the fast scenarios or features with a tag, for example @fast, we can apply a
logical AND to say we want to run scenarios that are tagged as @fast and either
@focus or @email:
$ cucumber --tags @fast --tags @focus,@email
Here we are using --tags twice. Each of them will be logically ANDed together.
Ideally, most of our scenarios are fast, and only a few are slow. So, instead
of tagging most of our scenarios with @fast, it makes more sense to tag the
few that are slow with @slow. If we want to run the scenarios that are not slow
(and at the same time @focus or @email), we can use negation (tilde):
$ cucumber --tags ~@slow --tags @focus,@email
Let’s look at another way to run a subset of scenarios—line numbers.
Filtering on Lines
You don’t need to tag your scenarios or features to run just a subset of them.
Cucumber also provides a convenient way to specify the line number of the
scenario you want to run. Here is an example:
$ cucumber features/something.feature --line 45
If the feature file has more than one scenario, it will run only the one on line
45. The line number can be anywhere in the feature, ranging from a comment
line to the last step (including a step table or doc string).
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You have probably noticed that Cucumber prints out the location of a feature
file with the line number in error messages.
features/something.feature:45
If you want to rerun the scenario that failed, just select the text and paste it:
$ cucumber features/something.feature:45
This is equivalent to using the --line option. The colon notation also allows you
to specify several line numbers, allowing you to specify several scenarios to
run:
$ cucumber features/something.feature:45:89:107
If you prefer, you can also do this using the --lines argument. Cucumber doesn’t
mind whether you say --line or --lines.
Filtering on Names
If tag and line filtering still doesn’t meet your needs, you can filter scenarios
based on name. Say, for example, that you want to run all scenarios that
have the text logout in their name and that they are scattered around several
feature files without a particular tag to identify them. Running them is just
a matter of the following:
$ cucumber --name logout
In a similar fashion, you can also --exclude scenarios with a certain name.
11.3 Changing Cucumber’s Output
Cucumber’s default behavior is to output results similar to the Gherkin source
text—with a little extra information such as colors, locations of matched step
definitions, highlighting of arguments, and so on. This isn’t the only way to
output results. Cucumber lets you use a different output format. For example,
if you want a minimal report with a single character per step, you can use
the progress formatter:
$ cucumber --format progress
..U--..F..
Each character represents the status of each step:
•
•
•
•
. means passing.
U means undefined.
- means skipped (or a Scenario Outline step).
F means failing.
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Changing Cucumber’s Output
• 195
Cucumber also has built-in formatters that output html, json, and junit. The
latter is handy if you are running Cucumber in a continuous integration (CI)
environment since most CI servers know how to interpret JUnit reports. More
on that in a minute.
Special Formatters
In addition to the formatters we have seen so far, Cucumber also bundles a
few formatters that create output that isn’t really meant to be read as a report
of the run. These formatters rather serve as a development aid.
The usage formatter lists all of the step definitions in your project, as well as
the steps that are using it. It shows you unused step definitions, and it sorts
the step definitions by their average execution time. The output from the usage
formatter is great for quickly finding slow parts in your code but also a great
way to get an overview of your step definitions.
The stepdefs formatter is similar to the usage formatter but with a little less
information.
Finally, there is the rerun formatter. This is a special formatter that creates
output like this:
$ cucumber -f rerun
features/one.feature:367 features/another.feature:91:117
Does this look familiar? This is the same kind of format we used to run a
subset of scenarios using line filtering, which we described earlier.
If all scenarios are passing, the rerun formatter doesn’t output anything at all.
However, if one or more scenarios fail, it will output their location so that you
can copy and paste the output to rerun just those scenarios. Being able to
do this saves a lot of time when fixing broken scenarios.
Formatting to File and Using Multiple Formatters
By default, all formatters will print their output to STDOUT. So, what do we do
if we want to see the usual pretty output but also have a html and rerun report?
This is where you have to use the --out option. It tells Cucumber to write the
report to a file instead of STDOUT. Here is an example:
$ cucumber -f pretty -f html --out cukes.html -f rerun --out rerun.txt
This tells Cucumber to write the HTML report to the file cukes.html, then rerun
output to rerun.txt, and finally display the pretty formatter’s output in the
console.
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Displaying Full Backtraces
Using the --backtrace option causes Cucumber to print a full backtrace for each
failure instead of a shortened one. This is often useful when you are hunting
bugs.
11.4 Specifying the Location of Step Definitions
Have you ever wondered how Cucumber finds your step definitions? There is
nothing in Cucumber that expects them to be under features/step_definitions. In
fact, if you renamed these two directories to jolly/jumper and ran cucumber jolly,
things would work just as well.
Cucumber recursively scans some directories for .rb files to load, and if there
are step definitions in them (or hooks or transforms), they get loaded. It’s
important to understand what directories Cucumber scans. Once you understand this, you will save yourself from a common source of confusion and
frustration. Let’s illustrate that with an example. Assume you have organized
your features and step definitions as follows:
features
├── billing
│
└── credit_card.feature
├── scoring
│
├── multi_player.feature
│
└── single_player.feature
└── step_definitions
├── billing_steps.rb
└── scoring_steps.rb
If you run all of the features with cucumber features or just cucumber, everything
will work great. Then, one day you add a new scenario to your credit_card.feature
file to support a new credit card. Then you run it:
$ cucumber features/billing/credit_card.feature:104 -f progress
UUUU
All of your steps show up as undefined, even though your new scenarios were
reusing some existing step definitions. The directories scanned for step definitions and support code are determined by the feature files (or directories)
you give it. If you give it a feature file, it will look underneath its directory. If
you give it a directory, it will look under that directory. To see where Cucumber
is looking for code, you can pass the --verbose option.
The solution to this common problem is to use --require to tell Cucumber
explicitly where to load code from. The correct way to run the previous feature
would be as follows:
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Managing Your Work in Progress (WIP)
• 197
Setting Tag Limits
Sometimes you need to keep a check on the number of scenarios with a particular
tag. You can ask Cucumber to fail if the number of scenarios matching a tag exceeds
a certain number, like this:
# Execute all scenarios tagged with @javascript, failing if
# more than ten are found.
$ cucumber --tags @javascript:10
$ cucumber features/billing/credit_card.feature:104 -f progress -r features
...F
Our code is now found and loaded, and we can carry on as we had intended,
working on our new, failing scenario. You can configure this to happen by
default using a custom profile, which we’ll show you in a few pages.
11.5 Managing Your Work in Progress (WIP)
Having a lot of pending or half-implemented features and scenarios is something you should try to avoid. It makes it hard to stay focused, and it also
has a negative effect on the lead time—the time from starting to releasing—
of each feature.1 A common term for started but unfinished work is work in
progress, often called just WIP. If the team keeps a low number of WIP, the
lead time of each feature will also be lower.
Cucumber can help you manage your WIP with the help of tags and the --wip
option. Try to make it a habit to tag each scenario that is being worked on
with @wip and remove the tag when it passes. Let’s say your team has agreed
to always keep the WIP at or below three scenarios. To enforce this, you could
run Cucumber with the following option:
$ cucumber --wip @wip:3
This has some interesting side effects. First, if Cucumber finds more than
three scenarios tagged with @wip, it will fail immediately without even running
any scenarios. This is an indication that too much is being worked on and
that some scenarios should be removed until the other ones are passing (and
the @wip tag is removed).
The other side effect is that if any scenarios pass (and remember, you are
running only the @wip ones), Cucumber will also fail. This kind of failure is a
reminder to remove the @wip tag.
1.
Kanban [And10]
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11.6 Using Profiles
As you get comfortable with the various command-line options Cucumber
has to offer and start to use more of them, it can be tedious to type it all on
the command line over and over again. Cucumber lets you store the commandline options to a cucumber.yml YAML file. This file must be placed either in your
project’s root directory or underneath a directory called config. Here is a sample
cucumber.yml file:
default: --tags ~@wip --require features
wip: --tags @wip:3 --wip --require features
Now, if you run cucumber --profile wip, the command-line options keyed with wip:
will be transparently appended to your command line. If you don’t specify a
--profile argument (and you have a cucumber.yml file), Cucumber will pick the
default: one.
Notice that we’ve added --require features to both profiles. This is because we
want Cucumber to load step definitions and support code from the root directory automatically, no matter what folder we run the features from.
11.7 Running Cucumber from Rake
Many projects use a build tool to perform common tasks. For Ruby projects,
Rake is the de facto build tool. Cucumber has a Rake task that makes it easy
to run Cucumber from Rake. If you are using Cucumber-Rails, which we
describe in Chapter 14, Bootstrapping Rails, on page 229, you will have Rake
tasks set up automatically.
If you are not using Rake, it’s still easy to set it up yourself. Try adding this
to a Rakefile in the root of your project:
require 'cucumber/rake/task'
Cucumber::Rake::Task.new # defines a task named cucumber
Now you can run your Cucumber features from Rake:
$ rake cucumber
Profiles from cucumber.yml will be picked up when you run Cucumber from
Rake, but you can also define Cucumber command-line options from the
Rakefile:
Cucumber::Rake::Task.new('cucumber_progress') do |t|
t.cucumber_opts = %w{--format progress}
end
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• 199
Now that you know how to run Cucumber both from its native command-line
interface and from Rake, you can also make your continuous integration
server run it. Cucumber (or Rake) exits with a status code of 1 if any scenarios
fail, so your continuous integration server can properly detect failure.
11.8 Running Cucumber in Continuous Integration
Many teams set up their continuous integration2 (CI) server to run Cucumber
every time someone shares changes with the rest of the team. Since it’s a
command-line tool, there is nothing fancy you need to do—just plop the
cucumber command into the CI project’s configuration.
You may want to use slightly different command-line options for CI than you
use on your own workstation. You can do this by defining a special profile
for the CI build (for example ci).
Being Strict
It’s common to have missing or pending steps while we’re working on a new
scenario. Some teams strive to keep the mainline (trunk) of the source
repository pristine, without any pending or missing steps.
CI systems detect failure by inspecting the exit status of the processes it’s
running, and by default Cucumber exits only with an error status (a nonzero
value) if there is one or more failing steps. If you are running Cucumber in a
CI environment, you may want to set it up to fail if anyone checks in missing
or pending steps.
If we pass the --strict option to cucumber, it will exit with a nonzero value if there
are any missing or pending steps as well as failing ones. You can inspect the
exit status yourself after running cucumber:
# OS X or Linux
$ echo $?
# Windows
$ echo %ERRORLEVEL%
Sharing Reports
Earlier in this chapter we saw how you can use the --format option to change
Cucumber’s output. If you pass --out JUNIT_DIR --format junit to Cucumber in your
ci profile, you can configure your CI server to pick up those reports from
JUNIT_DIR and analyze them. Some CI servers can generate a trend chart
2.
http://martinfowler.com/articles/continuousIntegration.html
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• Chapter 11. The Cucumber Command-Line Interface
showing you and your team how healthy your build stays over time. This is
a great way to get an indicator of whether the project is improving or decaying.
You can also pass the --out HTML_FILE --format html to get a full HTML report of the
results. This is particularly handy if you are using a browser automation tool,
because you can embed screenshots of the browser right into the HTML report.
You can learn more about this in Section 15.4, Taking Screenshots, on page
271.
11.9 What We Just Learned
Cucumber has a rich set of command-line options that give you full control
over how it behaves. You can do the following:
• Run a subset of scenarios with --tags, --name, --line/--lines, or path:line.
• Use the --format option to get progress, HTML, or JUnit reports.
• List step definition statistics with --format usage and --format stepdefs.
• Use the --require option to control where step definitions are loaded from.
• Limit the work in progress with --wip and tag limits.
• Define profiles in cucumber.yml and run them with a single --profile or -p option.
• Integrate Cucumber into your Rake scripts.
Try This
We left out a couple of command-line options so you can experiment a little
yourself. Here are some exercises you can try:
• Use the command line to list the Gherkin keywords in another language,
for example Pirate or LOLCAT. Just for fun, try to write a Cucumber scenario in one of those languages.
• Run a scenario with a step that is matched by two different step definitions, one defining one argument and another defining two. After you get
an Ambiguous error, run the scenario again, this time with --guess.
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CHAPTER 12
Testing a REST Web Service
Sometimes the user of the system we need to test isn’t a human being but
another computer program. For systems like these, the user interface is often
a REST1 web service. To automate tests against it, we need to make our
Cucumber step definitions talk to the web service as though they were a
regular client application.
There are two main approaches for testing a web application with Cucumber
—in-process and out-of-process. Figure 12, Two main approaches for testing
REST APIs with Cucumber, on page 202 gives a high-level overview of these two
approaches.
The preferred approach is usually in-process, which means that Cucumber
is running in the same Ruby process as your own application. There is no
running web server or HTTP traffic, and this is both fast to run and easy to
set up. Being able to easily reset state (usually in a database) between scenarios is another strength of the in-process approach, as we explained in Chapter
10, Databases, on page 173.
Your application doesn’t have to be written in Ruby in order to be testable
with Cucumber. Applications written in Java, .NET, PHP, or any other programming language can be tested using the out-of-process approach, which
means starting your application before Cucumber runs and then having
Cucumber talk to it using an HTTP client library.
This is obviously a very technical chapter. We’ll use the Ruby web framework
Sinatra to create a very simple web service from scratch. We’ve chosen Sinatra
because it allows us to build the web service in just a few lines of code,
meaning we can focus our attention on tests rather than implementation.
1.
REST stands for Representational State Transfer. See http://en.wikipedia.org/wiki/
Representational_state_transfer.
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Cucumber
Alternative 2:
Out-Of-Process
Alternative 1:
In-Process
HTTP Client
HTTP
Rack-Test
HTTP Server
Rack
Other Web frameworks
(Java, PHP, .NET etc)
Sinatra
Rails
Your App
Your App
Figure 12—Two main approaches for testing REST APIs with Cucumber
12.1 In-Process Testing of Rack-Based REST APIs
Let’s start with the first approach, where both Cucumber and your application
run in the same Ruby process. We’ll be dealing with a very simple REST API
for storing and retrieving fruit. It’s probably not the most useful system in
the world but should allow us to illustrate the fundamentals of REST and
Cucumber.
We’re going to build our web service from scratch. Create a new project with
a features directory in it, and create this file:
Download rest_web_services/00/features/fruit_list.feature
Feature: Fruit list
In order to make a great smoothie
I need some fruit.
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Scenario: List fruit
Given the system knows about the following fruit:
| name
| color |
| banana
| yellow |
| strawberry | red
|
When the client requests GET /fruits
Then the response should be JSON:
"""
[
{"name": "banana", "color": "yellow"},
{"name": "strawberry", "color": "red"}
]
"""
In the rest of this section we are going to implement this feature. We’ll see
how Cucumber can issue HTTP requests to our application.
Standing Up a Skeleton App—and Storing Some Fruit
When we run our List fruit feature with cucumber, we’ll see the usual snippets:
Given /^the system knows about the following fruit:$/ do |table|
# table is a Cucumber::Ast::Table
pending # express the regexp above with the code you wish you had
end
When /^the client requests GET \/fruits$/ do
pending # express the regexp above with the code you wish you had
end
Then /^the response should be JSON:$/ do |string|
pending # express the regexp above with the code you wish you had
end
Before we go ahead and paste the previous snippets into a Ruby file and fill
in the blanks, let’s look at each one. The first snippet is a domain-specific
step definition—it’s about our fruit system. The last two seem like more general-purpose step definitions for HTTP REST operations. As discussed in
Section 7.4, Organizing the Code, on page 128, we’ll put each of them in a file
that describes the domain concept they are related to. This makes it easier
in the future to find our step definitions. Paste the first one in a features/step_definitions/fruit_steps.rb file and the last two in a features/step_definitions/rest_steps.rb file.
Let’s start by making the first step pass. To keep things simple, we are not
going to use a database to store our fruit—we can store them in memory.
This means that in our Given step, we’ll just store our fruit in a (class) variable:
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Download rest_web_services/01/features/step_definitions/fruit_steps.rb
Given /^the system knows about the following fruit:$/ do |fruits|
FruitApp.data = fruits.hashes
end
Of course, this is going to cause the Given step to go from pending to failing,
because we don’t yet have a FruitApp class:
Feature: Fruit list
In order to make a great smoothie
I need some fruit.
Scenario: List fruit
Given the system knows about the following fruit:
| name
| color |
| banana
| yellow |
| strawberry | red
|
uninitialized constant FruitApp (NameError)
./features/step_definitions/fruit_steps.rb:2
features/fruit_list.feature:6
When the client requests GET /fruits
Then the response should be JSON:
"""
[
{"name": "banana", "color": "yellow"},
{"name": "strawberry", "color": "red"}
]
"""
Failing Scenarios:
cucumber features/fruit_list.feature:5
1 scenario (1 failed)
3 steps (1 failed, 2 skipped)
0m0.004s
We’re going to implement our little REST web service with the Sinatra web
framework because it is so simple. If you were to use a different Rack-based
web framework such as Rails, the Cucumber features and Ruby files under
the features directory would be exactly the same, but there would be much
more application code for us to include in the book. Let’s start by installing
all the gems we’re going to need. Create a Gemfile in the root of the project:
Download rest_web_services/01/Gemfile
source 'http://rubygems.org'
gem 'sinatra', '1.3.1'
gem 'json', '1.6.3'
group :test do
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gem 'cucumber', '1.1.3'
gem 'rspec', '2.7.0'
gem 'rack-test', '0.6.1'
end
We need Sinatra and JSON to run our web service; we need Cucumber to run
the tests, RSpec to make assertions in the step definitions, and Rack-Test to
automate the web service from our step definitions. Now tell Bundler to install
the gems:
$ bundle
With that out of the way, we can get on with building our web server. Create
a file named fruit_app.rb in the directory above the features directory. Add the
following code to that file:
Download rest_web_services/02/fruit_app.rb
require 'sinatra'
class FruitApp < Sinatra::Base
set :data, ''
end
We’ve created a class FruitApp that inherits from Sinatra’s base class; this will
become our web server. We need to tell Cucumber to load that file. We’ll create
a features/support/env.rb file to do that:
Download rest_web_services/02/features/support/env.rb
require File.join(File.dirname(__FILE__), '..', '..', 'fruit_app')
The first line loads the fruit_app.rb file from the root directory of our project—
two directories up from this file. Try to run cucumber now. It should make our
first step pass. It’s time to get into the REST business!
Poking Our Application with Rack-Test
Since we are running Cucumber in the same Ruby process as the application
itself, we have the luxury of being able to talk to it directly, without going
through HTTP or a web server. This is possible thanks to a nifty little Ruby
gem called rack-test. Rack-Test is a library that is designed to be used in tests
and that acts as a façade2 to your web application, very much in the same
way as a regular web server does. Rack-Test has methods for mimicking HTTP
requests from code. As shown in Figure 13, Testing an in-process Rack application with Cucumber, on page 207, we’ll be talking to our application through
2.
http://en.wikipedia.org/wiki/Facade_pattern
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Sinatra
Sinatra is a lightweight web framework for creating web applications. The simplest
Sinatra web application looks like this:
require 'sinatra'
get '/' do
'Hello world!'
end
Sinatra, like most other Ruby web application frameworks, is based on the low-level
web server interface Rack. In this chapter, we are using Rack-Test, a testing library
that can talk to any Rack-based web application. This means we could implement
the application in this chapter in a different Rack-based web framework, like Rails
or Ramaze—using the same Cucumber features and step definitions.
You can read more about Sinatra at http://sinatrarb.com.
Rack-Test, which exposes Rack’s API for talking to our application just like
an HTTP server would.
Let’s put Rack-Test to use in the /^the client requests GET \/fruits$/ step definition
in the rest_steps.rb file, and while we’re at it, let’s turn the request path into a
variable with a capture group—this makes our step definition usable for
other paths too.
When /^the client requests GET (.*)$/ do |path|
get(path)
end
We’re calling Rack-Test’s get method here, but how exactly does Cucumber
know about this method? Well, it doesn’t actually, so we have to wire it up.
The get method is defined in a module called Rack::Test::Methods, which gets
loaded when we require 'rack/test'. To wire it all up, we need to modify our env.rb
file a little more:
Download rest_web_services/03/features/support/env.rb
require File.join(File.dirname(__FILE__), '..', '..', 'fruit_app')
require 'rack/test'
module AppHelper
# Rack-Test expects the app method to return a Rack application
def app
FruitApp
end
end
World(Rack::Test::Methods, AppHelper)
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Cucumber
Rack-Test
HTTP
Server
Rack
Sinatra
Your App
Figure 13—Testing an in-process Rack application with Cucumber
Let’s take a look at this code. The last line with the World call registers two
Ruby modules within Cucumber: first Rack::Test::Methods, which defines the
HTTP simulation methods like get, and then our own helper module that we
define right above. Both these modules will be mixed into Cucumber’s World,
as we’ve explained in Chapter 8, Support Code, on page 133. The reason we
need our own little AppHelper is that Rack-Test needs to know which Rack
application it should talk to, and it expects an app method to be defined in
the same object that mixes in the other Rack-Test methods. This method
must return the class of our web app.
Now that we have Rack-Test properly wired up, let’s see what Cucumber has
to say:
Feature: Fruit list
In order to make a great smoothie
I need some fruit.
Scenario: List fruit
Given the system knows about the following fruit:
| name
| color |
| banana
| yellow |
| strawberry | red
|
When the client requests GET /fruits
Then the response should be JSON:
"""
[
{"name": "banana", "color": "yellow"},
{"name": "strawberry", "color": "red"}
]
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"""
TODO (Cucumber::Pending)
./features/step_definitions/rest_steps.rb:6
features/fruit_list.feature:11
1 scenario (1 pending)
3 steps (1 pending, 2 passed)
0m0.017s
Our second step is passing, so it looks like our GET request worked well. But
wait a minute! How is that possible? We haven’t implemented anything in
our fruit_app.rb yet. Why is the step passing? We’ll find out in the next section.
Comparing JSON
Although it might seem a little surprising that our second step is passing at
this point, let’s not worry about why. Instead, let’s continue to make our final
step pass, and everything will become clear. In this step, we want to compare
the response from the GET request with our expected JSON. Rack-Test always
lets us access the response of the last request by invoking the last_response
method, which returns an object that holds various information about the
response. We’re interested in the body, which is where we expect our web
app to write the JSON:
Then /^the response should be JSON:$/ do |json|
last_response.body.should == json
end
Let’s run Cucumber again. We’re getting an error message this time, and it’s
a quite long one. Let’s take some time to study it.
Feature: Fruit list
In order to make a great smoothie
I need some fruit.
Scenario: List fruit
Given the system knows about the following fruit:
| name
| color |
| banana
| yellow |
| strawberry | red
|
When the client requests GET /fruits
Then the response should be JSON:
"""
[
{"name": "banana", "color": "yellow"},
{"name": "strawberry", "color": "red"}
]
"""
expected: "[\n {\"name\": \"banana\", \"color\": \"yellow\"},\n
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{\"name\": \"strawberry\", \"color\": \"red\"}\n]"
got: "<!DOCTYPE html>\n<html>\n<head>\n <style type=\"text/css\">\n
body { text-align:center;font-family:helvetica,arial;font-size:22px;\n
color:#888;margin:20px}\n #c {margin:0
auto;width:500px;text-align:left}\n </style>\n</head>\n<body>\n
<h2>Sinatra doesn&rsquo;t know this ditty.</h2>\n <img
src=’http://example.org/__sinatra__/404.png’>\n <div id=\"c\">\n
Try
this:\n
<pre>get ’/fruits’ do\n \"Hello World\"\nend</pre>\n
</div>\n</body>\n</html>\n" (using ==)
Diff:
@@ -1,5 +1,21 @@
-[
- {"name": "banana", "color": "yellow"},
- {"name": "strawberry", "color": "red"}
-]
+<!DOCTYPE html>
+<html>
+<head>
+ <style type="text/css">
+ body { text-align:center;font-family:helvetica,arial;font-size:22px;
+
color:#888;margin:20px}
+ #c {margin:0 auto;width:500px;text-align:left}
+ </style>
+</head>
+<body>
+ <h2>Sinatra doesn&rsquo;t know this ditty.</h2>
+ <img src=’http://example.org/__sinatra__/404.png’>
+ <div id="c">
+
Try this:
+
<pre>get ’/fruits’ do
+ "Hello World"
+end</pre>
+ </div>
+</body>
+</html>
(RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/rest_steps.rb:6
features/fruit_list.feature:11
Failing Scenarios:
cucumber features/fruit_list.feature:5
1 scenario (1 failed)
3 steps (1 failed, 2 passed)
0m0.018s
Cucumber is telling us that it expected to get back the JSON we specified in
our feature, but instead it got some HTML back. What is going on here?
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What we’re seeing here is actually Sinatra’s 404 Page Not Found page, which it
shows for any HTTP request it doesn’t know how to serve. This begins to
explain why the second step was passing. Cucumber and Rack-Test were
able to make a GET request, but since we haven’t yet defined a route for /fruits,
the response of that request was a 404 Page Not Found. We actually see this in
the HTML in the error message if we look carefully.
What might surprise you is that Rack-Test didn’t raise an exception since it
got a 404 Page Not Found response, instead of the 200 Successful that we were
expecting. In fact, no HTTP error responses in the 4xx and 5xx response code
ranges will cause Ruby errors to be raised by Rack-Test. This is a deliberate
design decision by the creator of Rack-Test, and it has the benefit that you
can easily write tests for edge cases where an error is the expected behavior,
as well as happy-path scenarios like this one.
Now that we understand what is going on, let’s implement the /fruits route in
our web service. Back in your fruit_app.rb, edit it so it looks like the following:
Download rest_web_services/05/fruit_app.rb
require 'sinatra'
require 'json'
class FruitApp < Sinatra::Base
set :data, ''
get '/fruits' do
content_type :json
FruitApp.data.to_json
end
end
Running Cucumber again brings us just a few yards from the goal.
Feature: Fruit list
In order to make a great smoothie
I need some fruit.
Scenario: List fruit
Given the system knows about the following fruit:
| name
| color |
| banana
| yellow |
| strawberry | red
|
When the client requests GET /fruits
Then the response should be JSON:
"""
[
{"name": "banana", "color": "yellow"},
{"name": "strawberry", "color": "red"}
]
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Joe asks:
I Thought Scenarios Should Avoid Technical Terms
like JSON
It’s always important to make a scenario readable by a stakeholder. However, for a
REST interface, the stakeholder is going to be another programmer writing a client
for the REST interface. In such cases, it’s fine to expose technical details. For a human
user interface, such as an HTML web application, we should use nontechnical terms.
There’s more about this in Chapter 15, Using Capybara to Test Ajax Web Applications,
on page 245.
"""
expected: "[\n {\"name\": \"banana\", \"color\": \"yellow\"},\n
{\"name\": \"strawberry\", \"color\": \"red\"}\n]"
got:
"[{\"name\":\"banana\",\"color\":\"yellow\"},
{\"name\":\"strawberry\",\"color\":\"red\"}]"
(using ==)
Diff:
@@ -1,5 +1,2 @@
-[
- {"name": "banana", "color": "yellow"},
- {"name": "strawberry", "color": "red"}
-]
+[{"name":"banana","color":"yellow"},{"name":"strawberry","color":"red"}]
(RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/rest_steps.rb:6
features/fruit_list.feature:11
Failing Scenarios:
cucumber features/fruit_list.feature:5
1 scenario (1 failed)
3 steps (1 failed, 2 passed)
0m0.018s
Now the scenario is failing simply because the actual JSON has no spaces
and newlines, while the JSON from our scenario does. Of course, we could
make the scenario pass by removing whitespace and newlines from the scenario too, but that would make it very hard to read. Remember, our features
are supposed to serve as documentation too, not only automated tests. In
any case, it’s the data that’s significant in this scenario, not the whitespace.
What we really want to do is to parse the two JSON strings into an object
structure and compare those. This is just a small change:
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Then /^the response should be JSON:$/ do |json|
JSON.parse(last_response.body).should == JSON.parse(json)
end
Finally, our first REST feature is passing!
Feature: Fruit list
In order to make a great smoothie
I need some fruit.
Scenario: List fruit
Given the system knows about the following fruit:
| name
| color |
| banana
| yellow |
| strawberry | red
|
When the client requests GET /fruits
Then the response should be JSON:
"""
[
{"name": "banana", "color": "yellow"},
{"name": "strawberry", "color": "red"}
]
"""
1 scenario (1 passed)
3 steps (3 passed)
0m0.018s
Using Rack-Test makes it easy to test a REST interface with Cucumber. If we
were to write another scenario—perhaps testing how the application deals
with duplicate fruit—we would have to make sure that any data stored in the
previous scenario is cleaned away before the next one starts. With our simple
application, we could easily do this in a Before hook, which we described in
detail in Section 8.4, Using Hooks, on page 147. Since Cucumber is running
in the same process as the application, cleaning away previous data would
be simple—just call FruitApp.data = [] in a Before block. If our application was
using a proper database, we would delete all of the rows/records that were
created in the scenario instead, as described in Chapter 10, Databases, on
page 173.
Testing in-process is great when you have the option available to you, but
there are many more web services written in other languages than Ruby that
you’ll still want to be able to test. In the next section, we’ll decouple ourselves
from the Sinatra application and run it out of process so you can see how to
test a stand-alone web service.
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Matt says:
Comparing Data Is Less Brittle Than Comparing
Strings
The lesson we learn in this chapter about parsing both strings into JSON documents
before comparing them is a useful one to remember for other situations. When you
compare two strings in a test, you’re often leaving yourself open to brittle failures
that aren’t telling you anything useful. Parsing the string from the Gherkin feature
into more meaningful data can often mean you have more robust tests that fail only
when they should.
12.2 Out-of-Process Testing of Any REST API
In the previous section, we tested a REST API by running Cucumber in the
same Ruby process as our application. In this section, we are going to explore
how to test a REST API when Cucumber is running in a different process
than the application. Figure 14, Testing an out-of process web application with
Cucumber, on page 215 illustrates how this fits together. Cucumber and the
HTTP Client library run in one process, and the web application (the dotted
boxes) runs in another. We’ll be using the same application that we created
in the previous section, but you could just as well use an application written
in a different programming language. This is thanks to a handy little library
called HTTParty, which can issue HTTP requests to a web server.
We’ll start by changing our Gemfile. We’re going to add the HTTParty library
and another library called ChildProcess, which we’ll use to start the web
server process:
Download rest_web_services/07/Gemfile
source 'http://rubygems.org'
gem 'sinatra', '1.3.1'
gem 'json', '1.6.3'
group
gem
gem
gem
gem
end
:test do
'cucumber', '1.1.3'
'rspec', '2.7.0'
'httparty', '0.8.1'
'childprocess', '0.2.3'
We’ve also removed Rack-Test from the Gemfile since we’re no longer going
to be using it to talk to the web server.
Run bundle to install the new gems.
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HTTParty
Ruby’s standard library ships with an HTTP client called Net::Http. Many developers
have found this library is a little cumbersome to work with, so there is a host of HTTP
client libraries with simpler APIs available as Ruby gems.
One of these libraries is HTTParty, which we’ll use in this section. There are several
other similar libraries—RestClient, em-http-request, Curb, Restfulie, and some more.
They each have their strength and weaknesses, and it doesn’t matter much which
one you choose.
You can read more about HTTParty at http://httparty.rubyforge.com.
We never actually fired up our fruit application, so let’s put in place a missing
piece so we can do that.
We’re going to start the application via rackup, which is the Rack framework’s
command-line tool for starting Rack-based applications. The rackup commandline tool will look for a config.ru file in the current directory. We won’t go into
details about Rack in this book, so we’ll just provide a simple config.ru file so
we can start the application. Put the following file in the root directory, next
to your fruit_app.rb file:
Download rest_web_services/07/config.ru
require File.dirname(__FILE__) + '/fruit_app'
run FruitApp
Now we can start up our app. Let’s run it on port 9999:
$ rackup --port 9999
If you point your web browser to http://localhost:9999/fruits, you should get
a JSON response containing {}—we have no fruit in our system. We’re going
out of process now, so let’s remove all of the Rack-Test code from the previous
section. This boils down to deleting all the code in the features/support/env.rb file.
Go ahead and clean out that file, and then let’s run the feature again and see
where that leaves us:
Feature: Fruit list
In order to make a great smoothie
I need some fruit.
Scenario: List fruit
Given the system knows about the following fruit:
| name
| color |
| banana
| yellow |
| strawberry | red
|
uninitialized constant FruitApp (NameError)
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Cucumber
HTTP Client
HTTP
HTTP Server
Sinatra
Your App
Figure 14—Testing an out-of process web application with Cucumber
./features/step_definitions/fruit_steps.rb:2
features/fruit_list.feature:6
When the client requests GET /fruits
Then the response should be JSON:
"""
[
{"name": "banana", "color": "yellow"},
{"name": "strawberry", "color": "red"}
]
"""
Failing Scenarios:
cucumber features/fruit_list.feature:5
1 scenario (1 failed)
3 steps (1 failed, 2 skipped)
0m0.004s
Ouch! It looks like we broke something here. We get a uninitialized constant Object::FruitApp error in the first step. This is because when we cleared out our
features/support/env.rb file, we also removed the first two lines that load our application code. Should we add them back? It might be tempting, but this is
precisely what we are not going to do. Remember, we are now in a situation
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where Cucumber and our application are meant to run in two different
processes. For all Cucumber cares, our application may be an application
that isn’t even written in Ruby. We did the right thing by removing everything
from features/support/env.rb—we don’t want Cucumber to load a single line of
code from our web application!
This brings up an interesting question: how can we make the first step pass?
Our app is using an in-memory data store (a simple class variable). We need
some way to access this data store from Cucumber, which is going to be
running in a different process. There are many ways to make this happen,
but the essence of it is that we need to make our application’s data store
accessible from a different process.
One option would be to expose a new method over our HTTP API that allowed
a client (like our Cucumber tests) to add new fruit to the system with an HTTP
POST. POSTing to a special URL to reset a database is not an uncommon
approach. Just make sure that if you do this, the URL is disabled in your
production environment. Another route would be to refactor our application
to use a data store such as MySQL or MongoDB and use a database library
to insert data. If we did that, our step definition could put fruit in the system
by talking directly to the same database as our web application.
For the sake of simplicity, let’s use the second simplest data store after
memory—a file. This takes only a couple of small modifications to fruit_app.rb.
We’ll read the fruit from a JSON file and validate that it’s valid JSON while
we’re at it:
Download rest_web_services/08/fruit_app.rb
require 'sinatra'
require 'json'
class FruitApp < Sinatra::Base
set :data do
JSON.parse(File.read('fruits.json'))
end
get '/fruits' do
content_type :json
FruitApp.data.to_json
end
end
The fruits.json file will be read every time a request is made and asks for
FruitApp.data. Now it’s easy to do the right thing in the first step by modifying
features/step_definitions/fruit_steps.rb to write to our new file database.
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Download rest_web_services/08/features/step_definitions/fruit_steps.rb
Given /^the system knows about the following fruit:$/ do |fruits|
File.open('fruits.json', 'w') do |io|
io.write(fruits.hashes.to_json)
end
end
We’ve used another method on Cucumber::Ast::Table, hashes, which returns the
data in the table as an array of hashes: one hash per row in the table. The
column headings in the first row of the table are used as keys in the hash.
Now that you have made changes to your application, you need to restart it
again so that our code changes are picked up. It quickly becomes tedious to
keep two shells open and switch back and forth to restart our server. Let’s
tell Cucumber to start and stop the server instead. Let’s add some code back
to our features/support/env.rb file:
Download rest_web_services/08/features/support/env.rb
require 'childprocess'
require 'timeout'
require 'httparty'
server = ChildProcess.build("rackup", "--port", "9999")
server.start
Timeout.timeout(3) do
loop do
begin
HTTParty.get('http://localhost:9999')
break
rescue Errno::ECONNREFUSED => try_again
sleep 0.1
end
end
end
at_exit do
server.stop
end
If you need to start a different kind of web service, just substitute the rackup
command for the necessary command to start up your web server. The rest
of the pattern, polling the service until it’s up, should work perfectly whatever
platform your web service runs on.
The code starts the server in the background and waits up to three seconds
until it responds. The at_exit hook shuts it down just before Cucumber exits
when the tests have been run. With this in place, let’s run cucumber again:
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Joe asks:
What’s The Difference Between ChildProcess and
ServiceManager? How Should I Decide Which One
To Use?
In Chapter 9, Dealing with Message Queues and Asynchronous Components, on page
157, we showed you how to use the Service Manager gem to start and stop an external
process from your tests. Service Manager would also be a good fit for this situation
because it ships with the functionality to poll an external service until it is up,
something we’ve written by hand here.
ChildProcess is a more low-level library, which means it’s more flexible. That flexibility comes at the cost of needing more code to achieve common tasks, like the code
to start a web server in this chapter. We wanted to show you how to use both libraries,
but we’d suggest Service Manager is the better choice in most situations.
Feature: Fruit list
In order to make a great smoothie
I need some fruit.
Scenario: List fruit
Given the system knows about the following fruit:
| name
| color |
| banana
| yellow |
| strawberry | red
|
When the client requests GET /fruits
undefined method ‘get’ for #<Object:0x63756b65> (NoMethodError)
./features/step_definitions/rest_steps.rb:2
features/fruit_list.feature:10
Then the response should be JSON:
"""
[
{"name": "banana", "color": "yellow"},
{"name": "strawberry", "color": "red"}
]
"""
Failing Scenarios:
cucumber features/fruit_list.feature:5
1 scenario (1 failed)
3 steps (1 failed, 1 skipped, 1 passed)
0m0.005s
This is a bit like opening up a set of Russian dolls: each time a new step
passes, we learn more about what we need to do next. Our first step is passing
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again, but now the second step is failing. We no longer have a get method
available to make our request since we removed our Rack-Test code.
This is the first time we’ll put HTTParty—our HTTP client—to use. We need
to modify the steps in features/step_definitions/rest_steps.rb to use HTTParty instead
of Rack-Test:
Download rest_web_services/09/features/step_definitions/rest_steps.rb
require 'httparty'
When /^the client requests GET (.*)$/ do |path|
@last_response = HTTParty.get('http://localhost:9999' + path)
end
Then /^the response should be JSON:$/ do |json|
JSON.parse(@last_response.body).should == JSON.parse(json)
end
First, we load HTTParty with require 'httparty'. Then, we call HTTParty.get to issue
an HTTP request. Here we have to pass a full URL, which is why we tack on
'http://localhost:9999' before the path passed to the step definition. We store the
response in a @last_response instance variable, because HTTParty’s API is a little
different from Rack-Test. Finally, in the last step definition we refer to that
variable to get the body from the HTTP request. Let’s run the feature again:
Feature: Fruit list
In order to make a great smoothie
I need some fruit.
Scenario: List fruit
Given the system knows about the following fruit:
| name
| color |
| banana
| yellow |
| strawberry | red
|
When the client requests GET /fruits
Then the response should be JSON:
"""
[
{"name": "banana", "color": "yellow"},
{"name": "strawberry", "color": "red"}
]
"""
1 scenario (1 passed)
3 steps (3 passed)
0m0.065s
Great! If you’re following along, you’ll probably notice that the scenario feels
slower to run than the equivalent in-process test. This is the added overhead
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of waiting for the web server to start up before the scenario starts. Remember,
you pay this penalty only once per test run. Running Cucumber out-of-process
with HTTParty is just as successful as our in-process approach that used
Rack-Test. We didn’t change a single line of our feature files—all the changes
are nicely tucked away in our step definitions. The main difference was that
this time we executed real HTTP requests, and the tests took a little bit longer
to fire up.
12.3 What We Just Learned
When testing a REST web service with Cucumber, it’s generally preferable to
run Cucumber in-process—in the same process as your application. In this
chapter, we covered the two main approaches—in-process and out-of-process.
Although our example used the Sinatra web framework, the techniques used
in this chapter can be applied to other web frameworks too.
• Rack-based applications such as Ruby on Rails and Sinatra can be tested
in-process using Rack-Test, completely bypassing HTTP, making them
fast.
• Non-Rack-based applications run in a separate process from Cucumber
and have to be started before Cucumber runs.
• You can use indented JSON documents in your scenarios, as long as you
ignore whitespace when you compare them to documents produced by
your API.
Try This
Our Fruit application is very simple. It doesn’t provide an API to store fruit,
and the file-based database is very simplistic. Here are some new features
you can try to express with Cucumber and then implement:
• Add a scenario that starts with one fruit in the database, adds another
one via an HTTP POST, and then verifies that you now have two fruit.
• Refactor your code to use a proper database, like MySQL or MongoDB,
to store fruit. Make sure all scenarios are still passing and that you can
run each of them individually. Hint: use DatabaseCleaner to make sure
each scenario starts with a blank slate.
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CHAPTER 13
Adding Tests to a Legacy Application
In the real world, you don’t always get the luxury of working on shiny new
code. Reading a book like this can be a little bit frustrating because the examples all deal with nice, simple problems, usually in a new codebase.
We all know that software development isn’t really like that.
Even in the best teams we’ve worked on, there have always been a few dark
and ugly corners of the codebase where nobody really wanted to go. People
would sometimes disappear into there for days at a time and emerge exhausted
and confused, blinking in the bright sunlight.
Like an old abandoned mine, those areas of the codebase are dangerous. The
code is fragile, and the slightest change can cause other parts of the code to
collapse and stop working. Everyone knows this, and that’s why people are
reluctant to go in there: it’s stressful work.
If you had to go down an old mine tunnel, what would you do to make it safer?
You’d probably build some scaffolding to hold the roof of the tunnel up so
that it didn’t collapse—just enough to help you get in and get out again
safely.
You can think of automated tests like this. When you have to make a change
to an area of the code that you know is brittle, it’s scary. What is the thing
that you’re most afraid of?
Breaking something.
Automated tests can help you keep this fear at bay. If you make a change
and other parts of the code start to collapse, the tests will give you a warning
while you still have a chance to do something to correct it. But what if you
don’t have any tests?
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Even if you have recognized that automated testing can help your team write
better code, the prospect of adding tests to a large legacy codebase can seem
overwhelming. In this chapter, we’ll show you some simple techniques you
can use to help to solve the problem gradually, giving you added benefit each
step of the way.
This isn’t a technical recipe, but it will give you some useful techniques and
encouragement if you’re facing this situation.
Let’s start with the first tool you’ll need when you enter the mine: a flashlight.
13.1 Characterization Tests
In his excellent book Working Effectively with Legacy Code [Fea04], Michael
Feathers talks about two different types of tests, which he calls specification
tests and characterization tests.
Specification tests are the ones we’ve been talking about in the rest of this
book. They check that the code does what it’s supposed to. Ideally you write
them before you write the code itself and use them as a guide to help you get
the code into the right shape.
Characterization tests are different. You can think of them more like a science
experiment, where you test the properties of a mysterious substance by boiling
it or mixing it with other substances to see how it reacts. With characterization
tests, the aim is just to understand what the system currently does.
Characterizations tests apply perfectly to legacy code that has limited or no
tests and where the code is hard to read and understand. Here is our recipe,
adapted from Michael Feathers’, for creating a Cucumber characterization
test:
1. Write a scenario that exercises some interesting—but mysterious—behavior
of your system.
2. Write a Then step that you know will fail.
3. Wire up the step definitions and run the scenario. Let the failure in the
Then step tell you what the actual behavior is.
4. Change the failing Then step so that it describes the actual behavior of the
system.
5. Repeat.
As an example, let’s suppose we’re making some changes to the checkout
system for a supermarket. We’ve been asked to add a new special offer to the
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system, which was developed a couple of years ago by a firm of expensive
management consultants, who are sadly no longer with us. We’ve grabbed
the source code, managed to get the system to spin up on our development
machine, and have been poking around through the user interface. The code
is pretty gnarly and it’s hard to tell exactly what’s going on, but we noticed
something about shampoo. It looks like there might be an existing special
offer on shampoo bottles already baked into the code, but it’s hard to tell
exactly what the rules are. Let’s write a test:
Scenario: Buy Two Bottles of Shampoo
Given the price of a bottle of shampoo is $1.99
When I scan 2 bottles of shampoo
Then the price should be $0
We know that’s going to fail: they’re not going to give us the shampoo for free,
are they? (Steps 1 and 2.)
So, we wire up the step definitions to the system and run the scenario. Here’s
what happens:
Feature:
Scenario: Buy Two Bottles of Shampoo
Given the price of a bottle of shampoo is $1.99
When I scan 2 bottles of shampoo
Then the price should be $0
expected: 0
got: 1.99 (using ==) (RSpec::Expectations::ExpectationNotMetError)
./features/step_definitions/steps.rb:8
features/bogof.feature:5
Failing Scenarios:
cucumber features/bogof.feature:2
1 scenario (1 failed)
3 steps (1 failed, 2 passed)
0m0.003s
A-ha! Now we know what price the system is charging for two $1.99 bottles
of shampoo: $1.99. (Step 3.)
Now we update the Then step of our scenario to reflect our new understanding
of what the system does (step 4):
Scenario: Buy Two Bottles of Shampoo
Given the price of a bottle of shampoo is $1.99
When I scan 2 bottles of shampoo
Then the price should be $1.99
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We run the scenario again, and this time it passes. Great! We’ve added our
first characterization test. It’s not much, but it’s a start, and we know that
whatever we do to the code from now on, we’ll always have this scenario to
tell us whether we break this particular aspect of its behavior.
It looks like there’s a buy-one-get-one-free offer on shampoo, but we can’t be
sure from this single example. Following the recipe, we now need to repeat
steps 1 to 4 and add some more scenarios to give us some more clues as to
what the system is doing.
We can refactor the scenario into a scenario outline (see Chapter 5, Expressive
Scenarios, on page 61) to allow us to try different amounts and prices:
Feature: Special Offers
Scenario Outline: Shampoo
Given the price of a bottle of shampoo is $1.99
When I scan <number> bottles of shampoo
Then the price should be <total>
Examples:
| number | total |
| 1
| $0
|
| 2
| $1.99 |
We can now add examples into the table, one at a time. Each time we start
with a silly value for the total price and then run the scenario and let it tell
us what the real total is. Then we update the scenario to document that
behavior.
13.2 Squashing Bugs
Our legacy application is big and mysterious, and we could spend an awfully
long time writing characterization tests if we just started adding them aimlessly. So, assuming that we do want to grow our suite of automated tests,
where should we start?
One of the best ways to start practicing with Cucumber is when you have a
bug to fix. Bug reports generally come to you in the form of an example, so
they’re nice and easy to translate into Cucumber scenarios.
1. Translate the bug report into a Cucumber scenario. Show the scenario
to the person who reported the bug, and ask them whether it accurately
describes what they were doing.
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2. Wire up the step definitions and run the scenario. It should fail in the
same way as the real system did when the bug was first discovered. The
bug is trapped!
3. Examine the defective code, and think about what you’ll need to change.
If you’re unsure or worried about breaking some existing behavior, write
a characterization test scenario for it.
4. Fix the code so that the bug report scenario passes.
5. Run the characterization tests to check you didn’t break anything.
You’ll find that the bug report scenario acts as a driving force, helping you
focus on the code instead of having to keep running a manual test to see
whether the fix has worked.
Despite your new characterization tests, you may still find that you missed
something and introduced a new bug. That happens sometimes, and it would
have happened just the same if you hadn’t used any automated tests. If you
use the same recipe to fix that new bug and each new bug that comes along,
then gradually, over time, you’ll build up a solid suite of Cucumber scenarios.
Not only will those scenarios prevent any of these bugs from recurring, but
they’ll start to document the behavior of the system for anyone doing maintenance on it in the future.
13.3 Adding New Behavior
When you think about it, the process of adding new behavior to a system isn’t
so different from fixing a bug. The overall goal is to change some aspect of
how the system behaves, without breaking anything else.
Just as with bug fixing, we can use characterization tests to pin down the
surrounding behavior of the system to make sure it isn’t dislodged by our
work. Characterization tests can also be useful before that, while the new
feature is first being considered. You can use them to help understand how
much work is involved in the new feature by clarifying exactly what the system
currently does.
Here’s our recipe for adding new behavior to a legacy system:
1. Examine the new feature. If necessary, write a few characterization
scenarios to examine and clarify the current behavior of the system in
that area.
2. Now, with the new feature in mind, modify those scenarios or write new
ones to specify the desired new behavior.
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Matt says:
Features for Bug Fixes
We’ve just told you to use Cucumber to help you reproduce and trap bugs, so it’s
quite likely that you might end up writing a new feature and calling it something like
features/verify_bugfix_52553.feature. We’ve done this ourselves, and trust us—it doesn’t
make for great documentation!
There are two ways around this problem. If you judge that the scenario is relevant
enough to keep as business-facing documentation, then just talk to your team about
where to file it away tidily in your features. If you’re adding features to a legacy system,
that might will mean creating a new empty feature file about a whole big area of the
system and then just adding a single scenario to describe one aspect of its behavior.
That’s OK; you’ve created a space where other people can add more scenarios as they
come up. Try not to mention the bug itself as you write the scenario—just describe
the behavior you want as though it’s always been there.
On the other hand, if you decide that it’s such an obscure edge case that it isn’t
interesting enough to remain as business-facing documentation, you can just delete
the scenario once you’ve fixed the bug. That’s assuming you’ve used a unit test to
cover the changes you’ve made to make the fix, so you can be safe in the knowledge
that the bug won’t reappear.
3. Run through the scenarios with your team’s stakeholder representative
to check that you’re about to build the right thing. Correct the scenarios
with them if necessary.
4. Run the scenarios. If more than one fails, pick one, and examine the code
you’ll need to change to make it pass.
5. Write any extra characterization tests you need to give you the confidence
to change that code.
6. Change the code to make the scenario pass.
7. Repeat from step 4 until all the scenarios pass.
Sometimes we find that when we’re about to implement the change (step 6),
we see that the code we’re about to change is responsible for doing things
that we hadn’t anticipated when we wrote the original characterization tests
in step 1. At this point, we’ll stop and add some new characterization tests
(step 5) first if we think there’s a significant risk we could break something.
Just as with bug fixing, following this process means that you quickly get the
benefits of automated testing in the areas of the system where you most need
them: the ones that are most prone to change and instability.
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As you gradually build up your suite of Cucumber scenarios for your legacy
application, you’ll find you have more confidence to refactor and clean up the
code. This becomes a virtuous cycle, with cleaner code causing less bugs.
13.4 Code Coverage
Code coverage tools allow us to discover which specific lines of code in the
system were executed during a test. When you are starting to add tests to a
legacy application, it can be really useful to know your code coverage:
• If you know that a line of code isn’t covered by your tests yet, you can see
more clearly what kind of a characterization test you need to write.
• If you know that a line of code is covered by your tests, you can be more
confident in refactoring or changing it.
Provided you’re testing a Ruby application, recording your code coverage from
Cucumber tests is pretty easy. For Ruby 1.8 applications, you can use
Cucumber’s built-in Rake task:
Download legacy_applications/Rakefile
require 'cucumber/rake/task'
Cucumber::Rake::Task.new do |t|
t.rcov = true
end
If you now run rake -T in your project’s root directory, you’ll see a new Rake
task that you can run with rake cucumber. When you run it, a new folder is
created called coverage that contains a pretty HTML report showing exactly
which lines of code were executed during the test.
At the time of writing, there was no built-in support in Cucumber for collecting
code coverage statistics under Ruby 1.9. Instead, you need to install the
SimpleCov1 gem and add a couple of lines to your env.rb:
require 'simplecov'
SimpleCov.start
When your features finish running, you should find a code coverage report
in coverage/index.html.
13.5 What We Just Learned
Working with legacy code is always a challenge, but you can use Cucumber
tests to help make it a much more enjoyable challenge.
1.
http://rubygems.org/gems/simplecov
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Track Your Code Coverage for Team Encouragement
Code coverage is a much maligned metric of code quality. We’ve heard of managers
who’ve demanded that their teams achieve 100 percent code coverage. We’ve also
heard of teams that, under those circumstances, simply wrote a load of tests with no
assertions in them. The tests were exercising all the code, but they weren’t testing
anything!
As a source of internal feedback for the team, though, code coverage can be useful,
especially when you’re embarking on a long-term project to bring a legacy system
under the control of automated tests. Start measuring your code coverage today, and
come back every few weeks to measure it again. You should be pleased to see the
number is climbing all the time.
Another great related metric to track, which your manager might be more impressed
with, is the defect rate (number of new bugs discovered per week). If your Cucumber
tests are going to add any value to your customers, this is the most likely place it will
surface. As you add more test coverage, your team will make fewer and fewer mistakes,
and you should see your defect rate drop.
• Be pragmatic! Don’t exhaust yourself trying to retrofit a complete set of
Cucumber features for everything the system already does. Instead, add
them gradually, one at a time, as you need them.
• Use characterization tests to help you understand what the system is
already doing and to give you some security before you make a change.
• Every time you discover a bug, trap it with a new Cucumber scenario.
Every time you add new behavior to the system, start by describing it
with a Cucumber feature.
• Use code coverage to give you and your team feedback and encouragement
about your progress in getting the system under test.
• Enjoy the newfound confidence with which you can refactor and clean
up the code that’s covered by the tests.
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CHAPTER 14
Bootstrapping Rails
Cucumber was born in the Ruby on Rails community, and there are some
well-worn patterns for setting up a Rails application to work with Cucumber.
This chapter walks you through those steps, from creating a new Rails application right to making your first scenario pass. If you’re about to embark on
a Rails project, this chapter was written for you. Even if you don’t work with
Rails in your day job, you’ll learn how to work with libraries like FactoryGirl
and ActiveRecord that you can put to wider use, even on non-Ruby projects.
Picture the scene.
It’s Monday morning. The coffee is still steaming on your desk, too hot to
drink. Your boss bursts into the room.
I’ve got an amazing idea! We’re going to build a blogging platform, a microblogging platform. It’s like blogging, right, but your messages are limited to 140
characters. So, you could send them from a phone even! This is going to change
the world! We’re going to call it...Squeaker.
You look up, skeptically. He often does this on Mondays—he should get out
more, you think to yourself. This does seem like one of his better ideas,
though.
So, you open up your text editor and start to sketch out the first Cucumber
feature:
Download rails/01/features/see_messages.feature
Feature: See Messages
Scenario: See another user's messages
Given there is a User
And the User has posted the message "this is my message"
When I visit the page for the User
Then I should see "this is my message"
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Yeah, that’s it! says your boss. That’s definitely the first thing we should focus
on. Can you make it do that?
14.1 Running the Generators
Rails uses generators to help you set up your application with typical boilerplate code that you can then customize to your needs. First we’re going to
generate the Rails application, and then we’ll add the cucumber-rails plug-in and
use its generator to configure your application so it’s ready for you to start
driving it with Cucumber.
We start by creating our Rails application. We’re going to use the rails new
command with a single option:
$ gem install rails --version 3.1.3
$ rails new squeaker --skip-test-unit
The option doesn’t matter too much—those are parts of Rails that we’re not
going to use, so they’d just be cluttering up our code if we left them in.
Now we need to edit our new Rails application’s Gemfile to include the cucumberrails gem. We’re also including the rspec-rails gem, which we’ll use to make
assertions later, and finally we’re adding database_cleaner, a gem that will make
sure our database is cleaned up between each scenario:
Download rails/01/Gemfile
source 'http://rubygems.org'
gem 'rails', '3.1.3'
# Bundle edge Rails instead:
# gem 'rails',
:git => 'git://github.com/rails/rails.git'
gem 'sqlite3'
# Gems used only for assets and not required
# in production environments by default.
group :assets do
gem 'sass-rails',
'~> 3.1.5'
gem 'coffee-rails', '~> 3.1.1'
gem 'uglifier', '>= 1.0.3'
end
gem 'jquery-rails'
# To use ActiveModel has_secure_password
# gem 'bcrypt-ruby', '~> 3.0.0'
# Use unicorn as the web server
# gem 'unicorn'
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# Deploy with Capistrano
# gem 'capistrano'
# To use debugger
# gem 'ruby-debug19', :require => 'ruby-debug'
group
gem
gem
gem
end
:test do
'cucumber-rails', '1.2.1'
'rspec-rails', '2.7.0'
'database_cleaner', '0.7.0'
We’ve tucked the Cucumber gems away in a test group so they won’t be
installed when we deploy to production.
With that done, we can move our working directory into the new application’s
folder and run the Cucumber generator:
$ cd squeaker
$ rails generate cucumber:install
Let’s take a quick look at the files that the generator has given us:
config/cucumber.yml
Contains some profiles that you can use to run Cucumber with different
sets of options.
features/support/env.rb
This is the script Cucumber runs first when the tests start. It loads the
Rails environment and requires the various Cucumber and Capybara
libraries needed to test your Rails application.
lib/tasks/cucumber.rake
Gives your application a cucumber Rake task. You can edit this file to change
the default options for the Rake task or create new ones.
Now that we have a Rails application with Cucumber set up, let’s put the
feature into features/see_messages.feature:
Download rails/01/features/see_messages.feature
Feature: See Messages
Scenario: See another user's messages
Given there is a User
And the User has posted the message "this is my message"
When I visit the page for the User
Then I should see "this is my message"
Let’s see if we can put just a little flesh on the bones.
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14.2 Creating a User
To get our first step to pass, we need to be able to create a user in our system.
We could do that by walking around the UI, filling in the user registration
forms and clicking buttons, but actually that’s not the point of this feature.
Our goal is to build the page where you can see a user’s messages so we don’t
need to worry about all that user registration stuff.
Let’s imagine we have a fast-forward button, and we skip past all the user
registration to the point where the user has registered. What state is the
system in now?
Well, we don’t know for sure because we haven’t built those screens yet, but
it seems safe to assume that there would be a new row in the users table in
our database. To get the system into that state, we can use the Rails models
to add a User record to the system, just as though they had registered. A great
library to help us work with ActiveRecord, the library Rails uses to talk to the
database, is called FactoryGirl.1 Let’s add her to the test group in our Gemfile:
Download rails/02/Gemfile
group :test do
gem 'cucumber-rails', '1.2.1'
gem 'rspec-rails', '2.7.0'
gem 'database_cleaner', '0.7.0'
gem 'factory_girl', '2.3.2'
end
Now we can implement the step definition for our first step. We’ll create it in
a file called step_definitions/user_steps.rb:
Download rails/02/features/step_definitions/user_steps.rb
Given /^there is a User$/ do
Factory(:user)
end
We’re calling FactoryGirl’s special helper method Factory, telling it to create us
a standard instance of the User model. If you run the feature now, you should
see the following error:
Feature: See Messages
Scenario: See another user's messages
Given there is a User
Factory not registered: user (ArgumentError)
./features/step_definitions/user_steps.rb:2
features/see_messages.feature:3
1.
http://rubygems.org/gems/factory_girl
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• 233
And the User has posted the message "this is my message"
Undefined step: "the User has posted the message "this is my message""
(Cucumber::Undefined)
features/see_messages.feature:4
When I visit the page for the User
Undefined step: "I visit the page for the User" (Cucumber::Undefined)
features/see_messages.feature:5
Then I should see "this is my message"
Undefined step: "I should see "this is my message"" (Cucumber::Undefined)
features/see_messages.feature:6
Failing Scenarios:
cucumber features/see_messages.feature:2
1 scenario (1 failed)
4 steps (1 failed, 3 undefined)
0m0.811s
You can implement step definitions for undefined steps with these snippets:
Given /^the User has posted the message "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
When /^I visit the page for the User$/ do
pending # express the regexp above with the code you wish you had
end
Then /^I should see "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
Why? Well, we need to tell FactoryGirl how to create a user. Create a file called
features/support/factories.rb, and give it some very basic sample data:
Download rails/03/features/support/factories.rb
require 'factory_girl'
FactoryGirl.define do
factory :user do |f|
f.username 'testuser'
end
end
We haven’t given much thought to the attributes for our user yet. That’s OK,
because Rails will let us change the columns in the users table easily using
migrations, and our Cucumber features will always tell us whether things
are still working. Right now we can concentrate on doing something simple
and getting it to work.
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Joe asks:
Why Do I Need FactoryGirl When I Can Just Create
Records with ActiveRecord Directly?
It’s really easy to create rows in your database just using ActiveRecord directly. For
our User class, we could use this code:
User.create! :username => 'testuser'
The problem with doing this is that as the shape of your User evolves, more attributes
are added, and validation rules are implemented, the hash of data that you need to
pass will get longer and longer. Pretty soon it could easily look like this:
User.create! :username => 'testuser',
:password => 'password',
:password_confirmation => 'password',
:email => 'test@test.com',
:first_name => 'Test',
:last_name => 'User'
Now you have a bunch of problems. First, you have a duplication problem: each time
you add a new mandatory field to User, you have to hunt for every place where you’ve
called User.create! and add the new field to the hash, along with a sample value. Second,
you have an incidental detail problem. The precise attributes of the user are totally
irrelevant to our See messages scenario, yet there’s all this noise in the step definition
where we need to create a user. That’s distracting for anyone who has to come along
and modify this code later, especially in another scenario where one of those attributes
is actually relevant to what’s being tested.
One solution, which is still baked into Rails at the time of writing, is to use fixtures.
We explain the problems with using fixtures in Chapter 6, When Cucumbers Go Bad,
on page 85.
FactoryGirl is an implementation of the Test Data Builder pattern as first described
by Nat Pryce.a It allows you to configure what a standard instance of any ActiveRecord
database object should look like in a central place so that your test code is clutterfree. Remember that you can use ActiveRecord and FactoryGirl to set up data in any
SQL database, whether or not the application you’re testing is written in Ruby.
a.
http://www.natpryce.com/articles/000714.html
If we run the features again, we should have made some progress:
Feature: See Messages
Scenario: See another user's messages
Given there is a User
uninitialized constant User (NameError)
./features/step_definitions/user_steps.rb:2
features/see_messages.feature:3
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And the User has posted the message "this is my message"
Undefined step: "the User has posted the message "this is my message""
(Cucumber::Undefined)
features/see_messages.feature:4
When I visit the page for the User
Undefined step: "I visit the page for the User" (Cucumber::Undefined)
features/see_messages.feature:5
Then I should see "this is my message"
Undefined step: "I should see "this is my message"" (Cucumber::Undefined)
features/see_messages.feature:6
Failing Scenarios:
cucumber features/see_messages.feature:2
1 scenario (1 failed)
4 steps (1 failed, 3 undefined)
0m0.816s
You can implement step definitions for undefined steps with these snippets:
Given /^the User has posted the message "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
When /^I visit the page for the User$/ do
pending # express the regexp above with the code you wish you had
end
Then /^I should see "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
Ah yes, a new error. So, working our way from the outside-in, we’ve hit the
point where we need to actually create the User model. Don’t worry about the
undefined steps for now—we’ll get to those later. We know that the user needs
to have a username, so let’s use the Rails model generator to create our very
simple User model:
$ rails generate model User username:string
If we run the features now, we’ll see that—hooray!—FactoryGirl can now find
the User model, but there’s no users table in our test database. Let’s fix that:
$ rake db:migrate db:test:prepare
Run the features now, and you should see that the first step has passed.
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14.3 Posting a Message
To implement our second step, we’re going to cheat again and simulate the
posting of a message by calling the models directly. This allows us to focus
on building the messages page without getting too distracted. Let’s implement
the second step definition:
Download rails/05/features/step_definitions/user_steps.rb
Given /^the User has posted the message "([^"]*)"$/ do |message_text|
User.count.should == 1
Factory(:message, :content => message_text, :user => User.first)
end
Notice that we’ve made an assertion that there should be only one user in
the system. We know that in the feature we’re writing right now there’s only
one user, but it’s possible that this step definition could be reused in the future
by another scenario involving more than one and behave in surprising ways.
Since the step definition talks about the user, it’s implying that there’s only
one user in the system. So, we use the assertion to make sure that’s true.
Now when we run the features, of course poor old FactoryGirl complains that
she doesn’t know what a message should look like:
Feature: See Messages
Scenario: See another user's messages
Given there is a User
And the User has posted the message "this is my message"
Factory not registered: message (ArgumentError)
./features/step_definitions/user_steps.rb:8
features/see_messages.feature:4
When I visit the page for the User
Undefined step: "I visit the page for the User" (Cucumber::Undefined)
features/see_messages.feature:5
Then I should see "this is my message"
Undefined step: "I should see "this is my message"" (Cucumber::Undefined)
features/see_messages.feature:6
Failing Scenarios:
cucumber features/see_messages.feature:2
1 scenario (1 failed)
4 steps (1 failed, 2 undefined, 1 passed)
0m0.842s
You can implement step definitions for undefined steps with these snippets:
When /^I visit the page for the User$/ do
pending # express the regexp above with the code you wish you had
end
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Posting a Message
• 237
Joe asks:
When Do I Use the UI and When Do I Use Models
Directly to Create Records?
A Given means that something has happened in the past. If a Given describes stuff that
should be in the database, it is usually preferable to create those records directly
using the database (ActiveRecord)—without going through the UI. This gives us the
freedom to implement certain functionality without depending on other UI screens
to be developed first. It also runs faster and makes our step definitions simpler. The
RSpec Book [CADH09] calls this pattern DMA—Direct Model Access.
Then /^I should see "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
Let’s fix that, again by creating a very simple factory definition in features/
support/factories.rb:
Download rails/06/features/support/factories.rb
factory :message do |f|
f.association :user
f.content 'Test message content'
end
Again, when we run Cucumber, we’re told we need to create a Message model:
Feature: See Messages
Scenario: See another user's messages
Given there is a User
And the User has posted the message "this is my message"
uninitialized constant Message (NameError)
./features/step_definitions/user_steps.rb:8
features/see_messages.feature:4
When I visit the page for the User
Undefined step: "I visit the page for the User" (Cucumber::Undefined)
features/see_messages.feature:5
Then I should see "this is my message"
Undefined step: "I should see "this is my message"" (Cucumber::Undefined)
features/see_messages.feature:6
Failing Scenarios:
cucumber features/see_messages.feature:2
1 scenario (1 failed)
4 steps (1 failed, 2 undefined, 1 passed)
0m0.891s
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You can implement step definitions for undefined steps with these snippets:
When /^I visit the page for the User$/ do
pending # express the regexp above with the code you wish you had
end
Then /^I should see "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
We’ll fix that once more by generating our very basic Message model and then
running the database migrations:
$ rails g model Message user_id:integer content:string
$ rake db:migrate db:test:prepare
That got us past the previous error, but now we have uncovered another
missing piece:
Feature: See Messages
Scenario: See another user's messages
Given there is a User
And the User has posted the message "this is my message"
undefined method ‘user=’ for #<Message:0x63756b65> (NoMethodError)
./features/step_definitions/user_steps.rb:8
features/see_messages.feature:4
When I visit the page for the User
Undefined step: "I visit the page for the User" (Cucumber::Undefined)
features/see_messages.feature:5
Then I should see "this is my message"
Undefined step: "I should see "this is my message"" (Cucumber::Undefined)
features/see_messages.feature:6
Failing Scenarios:
cucumber features/see_messages.feature:2
1 scenario (1 failed)
4 steps (1 failed, 2 undefined, 1 passed)
0m0.957s
You can implement step definitions for undefined steps with these snippets:
When /^I visit the page for the User$/ do
pending # express the regexp above with the code you wish you had
end
Then /^I should see "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
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Associating a Message with a User
• 239
Each new error means we’ve made a little bit of progress, but we want to get
to passing! Our step is now failing where we’ve asked FactoryGirl to create
the message and given her a user to associate with the message. She hasn’t
been able to do that because we haven’t told Rails yet that the two objects
have a relationship.
14.4 Associating a Message with a User
We haven’t defined our user association on the Message model yet. Let’s do
that:
Download rails/08/app/models/message.rb
class Message < ActiveRecord::Base
belongs_to :user
end
Cucumber now outputs this:
Feature: See Messages
Scenario: See another user's messages
Given there is a User
And the User has posted the message "this is my message"
When I visit the page for the User
Undefined step: "I visit the page for the User" (Cucumber::Undefined)
features/see_messages.feature:5
Then I should see "this is my message"
Undefined step: "I should see "this is my message"" (Cucumber::Undefined)
features/see_messages.feature:6
1 scenario (1 undefined)
4 steps (2 undefined, 2 passed)
0m0.908s
You can implement step definitions for undefined steps with these snippets:
When /^I visit the page for the User$/ do
pending # express the regexp above with the code you wish you had
end
Then /^I should see "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
Great! Our two Given steps are passing. Notice how nicely our Cucumber steps
have driven us to create just the right code in the models. Now we have an
undefined step that we need to implement. This will be the first time we actually interact with the web interface of our application. We will do this with
Capybara, which is installed as part of Cucumber-Rails. Capybara will be
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fully explained in Chapter 15, Using Capybara to Test Ajax Web Applications,
on page 245. For now, let’s just use the visit(path) method that Capybara gives
us. Add another step definition to features/step_definitions/user_steps.rb:
Download rails/09/features/step_definitions/user_steps.rb
When /^I visit the page for the User$/ do
User.count.should == 1
visit(user_path(User.first))
end
Here we are using the Rails route user_path, which takes a User instance. We’re
just passing User.first since we know there is only one user in our database.
Running Cucumber again now tells us that Rails doesn’t know about user_path:
Feature: See Messages
Scenario: See another user's messages
Given there is a User
And the User has posted the message "this is my message"
When I visit the page for the User
undefined method ‘user_path’ for
#<Cucumber::Rails::World:0x63756b65> (NoMethodError)
./features/step_definitions/user_steps.rb:15
features/see_messages.feature:5
Then I should see "this is my message"
Undefined step: "I should see "this is my message"" (Cucumber::Undefined)
features/see_messages.feature:6
Failing Scenarios:
cucumber features/see_messages.feature:2
1 scenario (1 failed)
4 steps (1 failed, 1 undefined, 2 passed)
0m0.890s
You can implement step definitions for undefined steps with these snippets:
Then /^I should see "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
That’s not surprising—we haven’t created a UsersController yet, and we haven’t
mapped it in our Rails application’s routes.
14.5 Creating a Controller by Hand
It may be tempting at this point to run a Rails generator to generate the
controller, views, helpers, tests, and who knows what other files. We’ll resist
this temptation and implement the bare minimum by hand. This way, we
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don’t end up with a lot of code that isn’t tested and that we might not even
need.
Let’s map our controller to config/routes.rb:
Download rails/10/config/routes.rb
Squeaker::Application.routes.draw do
resources :users
end
Add app/controllers/users_controller.rb:
Download rails/10/app/controllers/users_controller.rb
class UsersController < ApplicationController
def show
end
end
And a view in app/views/users/show.html.erb with some temporary content:
Download rails/10/app/views/users/show.html.erb
Hello
Admittedly, we did take a couple of shortcuts here. A fundamentalist BDD
practitioner would have run Cucumber between each little code addition,
getting guidance at every little step on the way. We recommend doing this in
the beginning until you find your own comfort level regarding how much code
is safe to add, remove, or modify between each run. This is a trade-off between
development speed and confidence.
Many people set up their environment so that Cucumber runs in the background every time you save a file. Explaining how do this is beyond the scope
of this book, but we recommend you check out Guard3 or Watchr.4 They are
both easy to set up and fun to use!
With the route, controller, and view in place, let’s run Cucumber once more
to see where we’re at:
Feature: See Messages
Scenario: See another user's messages
Given there is a User
And the User has posted the message "this is my message"
When I visit the page for the User
Then I should see "this is my message"
Undefined step: "I should see "this is my message"" (Cucumber::Undefined)
features/see_messages.feature:6
3.
4.
https://github.com/guard/guard
https://github.com/mynyml/watchr
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1 scenario (1 undefined)
4 steps (1 undefined, 3 passed)
0m0.999s
You can implement step definitions for undefined steps with these snippets:
Then /^I should see "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
Whoa! We successfully made a request to our user page. The last step is still
undefined, so we need to implement that as well.
14.6 Implementing the View
Let’s make the last few changes to make our scenario pass. The next thing
we need to do is to implement the last missing step. Add the following to
features/step_definitions/view_steps.rb:
Download rails/11/features/step_definitions/view_steps.rb
Then /^I should see "([^"]*)"$/ do |text|
page.should have_content(text)
end
We’re using Capybara’s page object and have_content RSpec matcher here to
verify that a snippet of text is on the page. We’ll explain more about that in
the next chapter. This makes our step go from undefined to failing since the
view doesn’t show what we want it to show. Remember—we just hard-coded
a message in it.
We’ll work outside-in, starting with the app/views/users/show.html.erb view. Let’s
assume the controller will assign an @user variable:
Download rails/11/app/views/users/show.html.erb
<% @user.messages.each do |message| %>
<p><%= message.content %></p>
<% end %>
If you want, run Cucumber again. That will tell us that, no, there isn’t a
@user variable. Let’s fix our controller so that it loads the @user:
Download rails/11/app/controllers/users_controller.rb
class UsersController < ApplicationController
def show
@user = User.find(params[:id])
end
end
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This isn’t enough to make the scenario pass quite yet. Now we get a new error
because we haven’t added the other side to the one-to-many relationship
between User and Message. Adding that is simple, since we already created our
Message class with a user_id field:
Download rails/11/app/models/user.rb
class User < ActiveRecord::Base
has_many :messages
end
And finally—our feature is passing:
Feature: See Messages
Scenario: See another user's messages
Given there is a User
And the User has posted the message "this is my message"
When I visit the page for the User
Then I should see "this is my message"
1 scenario (1 passed)
4 steps (4 passed)
0m1.046s
Excellent. We haven’t actually seen the code in action in a browser yet, but
we’ve done all the hard work. And what’s more, we know that whatever we
do to the application in the future, this scenario will always guarantee that
this core functionality is working. It’s time to call the boss over for a demo.
14.7 What We Just Learned
Cucumber-Rails integrates Cucumber with Rails.
• We installed Cucumber-Rails in our Rails project by running the cucumber:install generator. This created several files that wire up Cucumber to
run scenarios against our Rails application.
• We wrote a feature about displaying data without creating any user interface to enter it. Being able to prioritize features this way makes us flexible
—we are not dictated by a strict implementation order.
• We saw how we can use FactoryGirl to populate our database in Given
steps.
• We saw how we can access our web interface using Capybara’s visit method.
Now that you have learned how to set up Cucumber in a Rails application,
it’s time to learn more about the full workflow. In the next chapter, you’ll
learn more as we add Ajax behavior to Squeaker.
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14.8 Try this
We never fired up our browser to see whether our Squeaker application actually works. Try to insert some sample users and messages in your development
database using the Rails console. Or better yet, implement a feature for entering messages through the user interface, driven by Cucumber.
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CHAPTER 15
Using Capybara to Test Ajax Web
Applications
One of the most popular ways to use Cucumber is to automate the testing of
web applications. Here is a dirty little secret:
Cucumber has no idea how to talk to a web application!
That’s right—it’s completely useless for that. Still, people keep using it to test
web applications. How come?
Remember, Cucumber isn’t much more than a tool that can parse Gherkin
feature files and execute step definitions. It doesn’t know how to talk to
databases, web apps, or any external system. People install other libraries
for this and use them in their step definitions and support code to connect
to those external systems.
At the time of writing, the most popular Ruby library for interacting with a
web application is Capybara.1 It provides an API for accessing web pages and
interacting with them in a way that is very similar to how a real user would
—entering text in text fields and text areas, checking checkboxes, clicking
links and buttons, and so on. Capybara allows you to plug in different drivers
that run those interactions in several different ways—using a real browser
like Firefox, IE, or Chrome, or a number of different browser simulators. In
this chapter, you’ll learn how to use Capybara and when to use the various
available drivers it provides.
Have you ever come to a website and thought: If only this site had a search
function... Or worse:
1.
http://rubygems.org/gems/capybara
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Joe asks:
What About Watir and Webrat?
Watir is the oldest web browser automation tool for Ruby. It was created in 2003 by
Bret Pettichord. The original Watir supported only Internet Explorer, but the more
recent Watir-WebDriver supports most mainstream web browsers.
Webrat was created in 2008 by Bryan Helkamp and is heavily inspired by Watir.
Webrat introduced a browser simulator for quickly running tests and integrated with
Selenium WebDriver for real browser tests.
Capybara was created in 2009 by Jonas Nicklas and is essentially an improved
implementation of Webrat with a slightly simpler design and is more up-to-date with
other frameworks and libraries.
We are not covering Watir or Webrat in this book because they are so similar to
Capybara—and Capybara is the most widely used of those libraries.
They might as well remove this search field—this thing never finds what I’m
looking for!
People have become so accustomed to search that they expect it to be in every
system they use, and they expect it to actually find what they are looking for.
In this chapter, we’ll explore Capybara’s most important features through the
development of a search function for the Squeaker application we started in
Chapter 14, Bootstrapping Rails, on page 229. We won’t get into detail about
advanced search engines, but you will get a good understanding about how
to specify how a search function should work.
Let’s start by implementing a simple search that consists of a text field, a
button, and a list underneath where the search results are displayed. The
napkin sketch in Figure 15, Search design, on page 247 shows what we want.
We’ll start off by implementing this feature without any Ajax. This will show
you the basics of working with Capybara, using Capybara’s Rack driver to
send commands directly to the Rails application. This works very similarly
to the in-process approach we showed you in Chapter 12, Testing a REST Web
Service, on page 201, where we used the Rack-Test gem to send web requests
to our web service running in the same process as our Cucumber tests (in
fact, Capybara’s Rack driver uses Rack-Test under the hood). When that’s
done, we’ll make our search more responsive using Ajax by switching to
Capybara’s Selenium driver. You’ll see how Capybara makes it easy to run
your tests against different browsers.
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Figure 15—Search design
15.1 Implementing a Simple Search Without Ajax
In Chapter 14, Bootstrapping Rails, on page 229, we dabbled a little bit in
Capybara’s API. We used the visit(path) method to go to a user’s page, and we
verified that messages were displayed on the screen using Capybara’s
have_content matcher. Let’s add a feature that will allow users to search for
messages. This will expose us to more of the goodness Capybara has to offer.
Start with the code we left off with at the end of the previous chapter and add
a new search feature to features/search.feature:
Download capybara/00/features/search.feature
Feature: Search
Scenario: Find messages by content
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I search for "I am"
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
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If you skipped the previous chapter, you can download the code to jump right
in at this point.
We’ve used a simple example where two out of the three messages that the
user has posted will match the search. Notice that we haven’t referred
specifically to any button clicks or other user interface details in this scenario.
Instead, we’ve been careful to use the language of our own domain: words
like posted, search, and results.
When you run this feature, you will see that all the steps are undefined.
Preparing Something to Search For
Our search isn’t going to find anything unless some messages already exist,
so before we get to do anything with Capybara, we have to add some messages
to the database. Knowing how to set up the database before each scenario is
essential to testing web applications, so we’ll show you how here. Add the
following step definition to features/step_definitions/user_steps.rb:
Download capybara/00/features/step_definitions/user_steps.rb
Given /^a User has posted the following messages:$/ do |messages|
user = Factory(:user)
messages_attributes = messages.hashes.map do |message_attrs|
message_attrs.merge({:user => user})
end
Message.create!(messages_attributes)
end
This step definition is a little complicated. Let’s examine it, starting at the
bottom. ActiveRecord’s create! method is invoked with an Array of Hash objects,
which lets us create several Message records in one fell swoop. Cucumber’s
2
Table class (our messages object) conveniently provides the hashes method to
convert it to just that—an Array of Hash. To link those messages to a user, we
modify the Array by adding a :user entry in each Hash. The first line of the step
definition creates that User. The messages_attributes variable will contain something
like this:
[
{"content"=>"I am making dinner", :user=>#<User id: 1>},
{"content"=>"I just woke up", :user=>#<User id: 1>},
{"content"=>"I am going to work", :user=>#<User id: 1>}
]
2.
See Chapter 4, Step Definitions: From the Outside, on page 39 to learn about tables.
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Navigating, Filling in Fields, and Clicking Buttons
With the first Given out of the way, let’s get to work with our first custom
Capybara step definition.
We decided to write our steps in a declarative style. When I search for "I am" is a
great example of a declarative step. What widgets the user interacts with will
be nicely hidden inside a single step definition. This makes our Gherkin much
simpler and expressive, but it also makes our scenarios much easier to
maintain. In the future, we might have many scenarios for search, and if we
decide to change the user interface, we only have to update our single step
definition instead of having to update a whole lot of scenarios.
To do this, we have to break the declarative step into concrete user interaction
steps that Capybara can deal with:
1. Navigate to the search page.
2. Fill in the search criteria in the search field.
3. Click the Search button.
All of these actions are easy to perform with Capybara. We’ll implement this
in a new file called features/step_definitions/search_steps.rb:
Download capybara/00/features/step_definitions/search_steps.rb
When /^I search for "([^"]*)"$/ do |query|
visit('/search')
fill_in('query', :with => query)
click_button('Search')
end
We are making several assumptions here that can be used to guide the implementation of the search. First, we expect the web app to respond to the /search
path. Second, we expect an input field named query to be on the rendered
page. Third, there should be a Search button we can click. None of this stuff
exists yet, so we have set ourselves up for failure—the good kind of failure
that tells us what to do next:
Fixing the Controller Code
Let’s run Cucumber and examine the output:
Feature: Search
Scenario: Find messages by content
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
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When I search for "I am"
No route matches [GET] "/search" (ActionController::RoutingError)
./features/step_definitions/search_steps.rb:2
features/search.feature:8
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
Undefined step: "the results should be:" (Cucumber::Undefined)
features/search.feature:9
Failing Scenarios:
cucumber features/search.feature:2
1 scenario (1 failed)
3 steps (1 failed, 1 undefined, 1 passed)
0m0.862s
You can implement step definitions for undefined steps with these snippets:
Then /^the results should be:$/ do |table|
# table is a Cucumber::Ast::Table
pending # express the regexp above with the code you wish you had
end
Our second step is failing, but this doesn’t mean there is something wrong
with our step definition. It’s our application that is wrong. In Chapter 14,
Bootstrapping Rails, on page 229, we described the overall flow you go through
when making a step pass in a Rails application, but let’s repeat it quickly
here.
The exception from Rails tells us that we need to add a route:
Download capybara/01/config/routes.rb
Squeaker::Application.routes.draw do
resources :users
resource :search, :only => :show, :controller => :search
end
Now, Cucumber will complain about a missing controller, so we’ll add that:
Download capybara/01/app/controllers/search_controller.rb
class SearchController < ApplicationController
def show
end
end
We have no view, so we’ll add that as well. Let’s just enter some hard-coded
text for now:
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Download capybara/01/app/views/search/show.html.erb
Search page
With the route, controller, and dummy view, we are able to get a little further.
Let’s Give Capybara Something to Work On
Cucumber now fails with the following output:
Feature: Search
Scenario: Find messages by content
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I search for "I am"
cannot fill in, no text field, text area or password field with id, name,
or label ’query’ found (Capybara::ElementNotFound)
(eval):2
./features/step_definitions/search_steps.rb:3
features/search.feature:8
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
Undefined step: "the results should be:" (Cucumber::Undefined)
features/search.feature:9
Failing Scenarios:
cucumber features/search.feature:2
1 scenario (1 failed)
3 steps (1 failed, 1 undefined, 1 passed)
0m0.961s
You can implement step definitions for undefined steps with these snippets:
Then /^the results should be:$/ do |table|
# table is a Cucumber::Ast::Table
pending # express the regexp above with the code you wish you had
end
Capybara is telling us that it can’t find the search field where we’re entering
the search criteria. As you see from the error message, Capybara says it knows
how to locate a text field based on id, name, or label. We don’t need a label for
our input field, so all we need to add is a field with a name="criteria" attribute.
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We also need a Search button, so we’ll put everything in a form that issues a
GET request to the same page.3 Our modified view now looks like this:
Download capybara/02/app/views/search/show.html.erb
<form id="search" method="get" action="/search">
<fieldset>
<input type="text" id="query" name="query" />
<input type="submit" value="Search" />
</fieldset>
</form>
Now Cucumber passes the search step, and the last verification step remains
undefined:
Feature: Search
Scenario: Find messages by content
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I search for "I am"
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
Undefined step: "the results should be:" (Cucumber::Undefined)
features/search.feature:9
1 scenario (1 undefined)
3 steps (1 undefined, 2 passed)
0m1.082s
You can implement step definitions for undefined steps with these snippets:
Then /^the results should be:$/ do |table|
# table is a Cucumber::Ast::Table
pending # express the regexp above with the code you wish you had
end
Verifying Page Content
Our last step definition will require some extra thought. We are going to use
the value of the query URL parameter to run a database query and display the
results in a list (an <ol> element with <li> elements for each result).
3.
Using GET instead of POST makes searches easier to share—users can paste the search
URL into emails and other systems, or they can bookmark them. Here is an example
search URL: http://localhost:3000/search?query=I%20am.
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To compare the contents of the list on the search page with the expected
values in the Gherkin table, we need to extract the interesting bits from the
markup. This is easy once you have done it a few times, but at first it can be
a little daunting because it involves Capybara’s Capybara::Node::Finders API and
the use of CSS selectors.
This leaves us in a little bit of a tricky situation. We’re about to write nontrivial
step definition code to test nontrivial application code. Where do we start? A
useful technique in situations like this is to create a sketch of the solution.
We are going to hard-code the markup we expect to see in our view, without
any application logic at all. This will serve as scaffolding to support our test.
Let’s just modify our app/views/search/show.html.erb view so it contains exactly what
we want:
Download capybara/03/app/views/search/show.html.erb
<form id="search" method="get" action="/search">
<fieldset>
<input type="text" id="query" name="query" />
<input type="submit" value="Search" />
</fieldset>
<ol class="results">
<li><a href="/users/2/messages/20">I am making dinner</a></li>
<li><a href="/users/2/messages/21">SHOULD NOT BE HERE</a></li>
<li><a href="/users/2/messages/22">I am going to work</a></li>
</ol>
</form>
Actually, this isn’t exactly what we want. The view has the markup structure
we want but not the correct data! (There is a row too many.) This is a very
powerful technique. We are deliberately making our hard-coded view be
slightly wrong. This allows us to verify that our step definition will detect the
incorrect (hard-coded) result and display a proper error message. Then we
can focus on writing the step definition code correctly without worrying that
we have made a mistake in either the application logic or the step definition
logic, not knowing where the mistake was.
Extracting Data from the Page
Let’s start by constructing an Array of Array to hold the expected search results
from the page. (We’ll see in a minute how this can be used to compare against
a Gherkin table):
Download capybara/03/features/step_definitions/search_steps.rb
Then /^the results should be:$/ do |expected_results|
results = [['content']] + page.all('ol.results li').map do |li|
[li.text]
end
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puts results.join("\n")
pending
end
The page.all('ol.results li') call will return an Array of Capybara::Element objects, each
one representing an <li> element that contains a single <a> element. We’re
calling map on the Array to convert each Capybara::Element to another Array of Strings.
Finally, we’re using Cucumber’s puts method to print it out the console so we
can verify that our conversion is what we intended.
The [['content']] in the beginning is there to ensure our first row is the same as
the one we’re sending in from Gherkin—having the same values in the top
row is necessary in order to compare a Gherkin table with actual values.
Running Cucumber prints the following:
Feature: Search
Scenario: Find messages by content
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I search for "I am"
Then the results should be:
content
I am making dinner
SHOULD NOT BE HERE
I am going to work
| content
|
| I am making dinner |
| I am going to work |
TODO (Cucumber::Pending)
./features/step_definitions/search_steps.rb:14
features/search.feature:9
1 scenario (1 pending)
3 steps (1 pending, 2 passed)
0m1.002s
That looks about right! We are successfully extracting data from our web
page.
Using Table Diffs
Now that we are confident that we are properly extracting data from the page,
let’s compare it to our Gherkin table that contains the expected results. The
table object that gets passed to your step definition is an instance of Cucumber::Ast::Table, and one of the lesser known but extremely powerful methods on
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this class is the diff! method. It takes a single argument that it expects to be
an Array of Array representing rows and columns. If all the values are equal,
the step definition passes. If not, the step definition fails, and a diff is printed
out. Let’s put it to use:
Download capybara/04/features/step_definitions/search_steps.rb
Then /^the results should be:$/ do |expected_results|
results = [['content']] + page.all('ol.results li').map do |li|
[li.text]
end
expected_results.diff!(results)
end
Will Cucumber give us a proper error message?
Feature: Search
Scenario: Find messages by content
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I search for "I am"
Then the results should be:
| content
|
| I am making dinner |
| SHOULD NOT BE HERE |
| I am going to work |
Tables were not identical (Cucumber::Ast::Table::Different)
./features/step_definitions/search_steps.rb:13
features/search.feature:9
Failing Scenarios:
cucumber features/search.feature:2
1 scenario (1 failed)
3 steps (1 failed, 2 passed)
0m0.975s
It looks like it does. If you have colors enabled in your command window, you
will see the surplus row colored gray. If there had been missing rows, they
would have been yellow. Likewise for columns. We have built up confidence
that our somewhat complicated step definition will properly detect errors.
Now let’s get rid of the hard-coded parts and implement the search properly.
We’ll start by changing the view to loop over an array of Message and produce
the same markup as our hard-coded markup:
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Download capybara/05/app/views/search/show.html.erb
<form id="search" method="get" action="/search">
<fieldset>
<input type="text" id="query" name="query" />
<input type="submit" value="Search" />
</fieldset>
<ol class="results">
<% @messages.each do |message| %>
<li><%= link_to(message.content, [message.user, message]) %></li>
<% end %>
</ol>
</form>
If we run Cucumber again, we will get an error message from the view. This
is because we haven’t assigned anything to the @messages variable in our
controller.
In our controller we are just going to take the query parameter and ask the
model class to do the search for us:
Download capybara/05/app/controllers/search_controller.rb
class SearchController < ApplicationController
def show
@messages = Message.like(params[:query])
end
end
We could have implemented the search logic in the controller, but it is a
wiser design decision to put that in the model. That allows us to unit test it
in isolation later if we want. Here is what it looks like:
Download capybara/05/app/models/message.rb
class Message < ActiveRecord::Base
belongs_to :user
def self.like(content)
content.nil? ? [] : where(['content LIKE ?', "%#{content}%"])
end
end
We’re making sure the like method returns an empty array in case the argument is nil, which it will be if the request doesn’t include a query parameter.
Now that the query logic is implemented, we will get an error message from
Rails saying it can’t generate the link. This is because we haven’t defined a
route for the messages yet. That’s easy to do:
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Download capybara/05/config/routes.rb
Squeaker::Application.routes.draw do
resources :users do
resources :messages
end
resource :search, :only => :show, :controller => :search
end
And finally Cucumber is happy:
Feature: Search
Scenario: Find messages by content
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I search for "I am"
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
1 scenario (1 passed)
3 steps (3 passed)
0m1.018s
Try This
Before we head on to learn about Ajax, here are some small exercises you
can try, to learn more about Capybara and Cucumber’s table diffing:
• Add an extra column in the results table.
• Add a feature for posting messages through the UI so you can try the app
—we never ran it yet!
15.2 Searching with Ajax
Our users are ecstatic about the search feature we released, and Squeaker
has taken over most of the world, leaving millions of messages in our system.
Some of the users have complained that despite the new search functionality,
it takes too long to find what they are looking for. During usability testing
sessions, we also discovered that many of the users don’t even know what
they are looking for!
We have come up with an idea that we think might improve this. We’re going
to try to make search results more incremental by displaying them as the
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user types—even before they hit the Search button. This is described by a
new scenario:
Download capybara/06/features/search.feature
Scenario: Find messages by content using auto-search
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I enter "I am" in the search field
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
There is a subtle but essential difference in our When step here. We’re only
entering text, and unlike the When step in our previous scenario, we are not
submitting the form by clicking the button or hitting the Enter/Return key.
We have an idea about how to implement this feature—we’ll issue an Ajax
request whenever the user types a character, and when the response comes
back, we’ll display the results on the same page without doing a full page
load.
Using Selenium
When we implemented our basic search feature, we used Capybara to access
our web interface using Capybara’s Rack driver, which is what Capybara uses
by default. Capybara’s Rack driver is a browser simulator implemented in
Ruby that connects directly to the web server interface of your Rails application, making it nice and fast. While it knows how to parse the HTML on our
page and create a simplified DOM4 that we can interact with and query, it
completely ignores any JavaScript on the page because it doesn’t have a
JavaScript engine built in. So, how can we use Capybara to test the JavaScript-based autosearch we’re about to write?
We have to tell Capybara to use a driver that supports JavaScript instead of
the more limited Rack driver. Capybara, being one of Cucumber’s best friends,
defines a couple of tagged hooks, as described in Tagged Hooks, on page 147,
to make this easy. One of those tagged hooks will run for each scenario tagged
with @javascript and set up Capybara to use a JavaScript-aware driver instead
of the default one for any scenario carrying the same tag. Capybara’s default
4.
The Document Object Model is a tree-structure representing elements in a HTML page:
http://www.w3.org/DOM/.
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Capybara Drivers: Pros and Cons
Capybara makes it possible to plug in different drivers, which are different strategies
for connecting to a web application. They all sit behind the public Capybara API you
will be using (see Section 15.3, The Capybara API, on page 268), and trying a different
driver is usually a one-line change.
Some drivers ship with Capybara itself, while others are third-party libraries. They
each have their strengths and weaknesses, which we have tried to summarize here:
Driver
Good
Bad
Rack
Fast and simple.
No JavaScript support. Works only
with Ruby/Rack
applications.
Selenium
Real browser with JavaScript support. Works with web applications
written in PHP, Java, .NET, and so
on.
Slow. Needs a desktop operating
system to run.
CapybaraWebkita
Fast headless browser with JavaScript support.
Runs only on Linux and OS X.
Hard to install.
a.
http://rubygems.org/gems/capybara-webkit
JavaScript driver uses Selenium6 to interact with our application. Let’s add
that @javascript tag to our scenario to see how it works:
Download capybara/07/features/search.feature
@javascript
Scenario: Find messages by content using auto-search
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I enter "I am" in the search field
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
Running this feature will make a browser appear, and all of the interaction
now happens via the real browser. If your web application is based on the
Rack API (most Ruby-based web frameworks are), Capybara also takes care
6.
Selenium is a web browser automation tool that will open a real browser to interact
with a web server. You can learn more about Selenium at http://seleniumhq.org/.
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of starting your application’s web server in a separate thread before opening
the browser.
Feature: Search
Scenario: Find messages by content
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I search for "I am"
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
@javascript
Scenario: Find messages by content using auto-search
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I enter "I am" in the search field
Undefined step: "I enter "I am" in the search field" (Cucumber::Undefined)
features/search.feature:22
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
2 scenarios (1 undefined, 1 passed)
6 steps (1 skipped, 1 undefined, 4 passed)
0m1.058s
You can implement step definitions for undefined steps with these snippets:
When /^I enter "([^"]*)" in the search field$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
Unsurprisingly, Cucumber exits with a missing step definition. We need to
tell it how to enter text in a field without submitting the form. That’s easy!
We’ll implement the undefined step definition almost like the one we used in
our previous scenario, except this time we won’t click the Search button—we
are only going to fill in the field:
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Running Capybara Against Non-Ruby Applications
Capybara isn’t just limited to testing Ruby on Rails applications. You can very easily
configure Capybara to automate any Ajax web application, but you’ll need to add a
few lines of configuration to a Ruby file in your features/support directory. Here’s what
you need to do:
Capybara.run_server = false
Capybara.current_driver = :selenium
Capybara.app_host = 'http://www.your-test-server.com'
This tells Capybara not to try to start a Rack server and configures it to use the Selenium driver by default. The last setting, app_host, means that when you call visit('/login'),
Capybara will actually visit the URL http://www.your-test-server.com/login, saving you from
having to duplicate the hostname throughout your test code.
You’ll need to start the web server yourself, which you can do automatically using
the ServiceManagera gem or using the technique explained in Section 12.2, Out-ofProcess Testing of Any REST API, on page 213.
a.
http://rubygems.org/gems/service_manager
Download capybara/08/features/step_definitions/search_steps.rb
When /^I enter "([^"]*)" in the search field$/ do |query|
visit('/search')
fill_in('query', :with => query)
end
If you run the feature again and look carefully, you will see that the search
field is populated with the search text from our Gherkin scenario before the
browser is closed when the scenario is done. Neat! This leaves us with only
one more pending step—the one where we need to verify that intermediate
search results are coming back. It’s time to take a little break and think about
how we are going to implement this with Ajax and dynamic HTML.
Designing Our Live Search
When the user types in the search field and waits a short time, the browser
will issue an Ajax GET request identical to the one we used for our nonJavaScript version, with one small modification: the request will have an
additional Accepts HTTP header, indicating to the server that we want the
response as JSON (instead of HTML). When the response comes back to the
browser, we’ll iterate over the search results in the JSON we get back and
create those <li> elements dynamically with JavaScript.
Implementing this in JavaScript, even with the help of jQuery, will require
somewhere between twenty and sixty lines of code, depending on your style.
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Matt says:
Pausing Capybara
It can often be quite frustrating watching Capybara’s browser flash past something
that you want to take a closer look at. An easy trick to get Cucumber, and therefore
Capybara, to pause during a step is to call Cucumber’s ask method in the step definition. You can use it like this:
When /^I enter "([^"])*" in the search field$/ do |query|
visit('/search')
fill_in('query', :with => query)
ask('does that look right?')
end
An alternative is to use a debugger statement to pause the code, which will mean
installing a debugger. For Ruby 1.9, you need ruby-debug19.a This gives you the added
flexibility of being able to actually try commands on the fly. I especially like to use
this when I need to compose a tricky selector in Capybara.
a.
http://rubygems.org/gems/ruby-debug19
This is not an unsurmountable amount of code, but running Cucumber every
time you make a small change to this code is something we recommend
against because the feedback loop will be too slow. So, how do we proceed
now? There are two main directions you can take from here: TDD or not.
JavaScript TDD
Developing JavaScript with TDD used to be hard to do, because of a lack of
good tools, but this is a thing of the past. Unfortunately, Cucumber is not
one of those tools—it’s too high level. Low-level TDD with JavaScript is beyond
the scope of this book, but if you want to give it a try, we can recommend
QUnit9 or Jasmine.10 Test-Driven JavaScript Development [Joh10] is an excellent book that treats the topic really well.
Without JavaScript TDD
This is how we all started programming. Just write the code and test it manually! Since JavaScript TDD is a big topic that we are not going to cover in
this book, we are going to cheat a little and “just write the code.” We are going
to add a couple of messages to the development database using the rails console,
start up the web server, and code until we have something that works, testing
9. http://docs.jquery.com/QUnit/
10. http://pivotal.github.com/jasmine/
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our live search manually in the browser. When we think we have something
that works, we can run Cucumber to get a final verification.
This approach is not ideal—on real projects we would use TDD for our JavaScript as well. Still, our Cucumber scenario both will serve as validation and
will protect us against regressions should someone change the JavaScript in
the future. So, without further ado, we’ll just give you some JavaScript code
that we developed exactly this way. Create a new file in app/assets/javascripts/search.js with the following content:
Download capybara/09/app/assets/javascripts/search.js
function Search(form) {
this.form = form;
}
Search.prototype.queue = function (query) {
if (this.timer) {
clearTimeout(this.timer);
}
var self = this;
this.timer = setTimeout(function () {
self.search(query);
}, 150);
};
Search.prototype.search = function (query) {
var self = this;
jQuery.ajax({
url: this.form.action,
type: this.form.method,
data: {'query': query},
success: function(results) {self.render(results)},
contentType: 'application/json',
dataType: 'json'
});
}
Search.prototype.render = function (results) {
var html = "";
for (var i = 0, l = results.length; i < l; ++i) {
var url = '/users/' + results[i].user_id + '/messages/' + results[i].id;
html += '<li><a href="' + url + '">' + results[i].content + '</a></li>';
}
jQuery(this.form).find('ol.results').html(html);
}
jQuery.fn.search = function () {
this.each(function () {
var search = new Search(this);
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var input = jQuery(this).find("input[type=text]");
input.bind('keyup', function () {
search.queue(this.value);
});
});
};
jQuery(function() {
jQuery('#search').search();
});
This code defines a jQuery search plug-in and activates it on the input element
with a DOM ID of search. Whenever a user (or Selenium!) enters a character,
the browser fires the keyup event, and this starts a timer. If a delay of 150ms
elapses without any more characters being typed, it issues an Ajax request
with the search. We use the delay so that we don’t hammer our server with
search requests if the user is a really fast typist. This request also indicates
that it would like to have the response back as JSON. When the response
successfully comes back with the search results in a JSON array, we iterate
over them and render our search results.
Making the Web App Return JSON
As we mentioned earlier, we want the response from the search request to
contain JSON when the client explicitly says it wants JSON. This is just a
little tweak to the SearchController:
Download capybara/09/app/controllers/search_controller.rb
class SearchController < ApplicationController
respond_to :html, :json
def show
@messages = Message.like(params[:query])
respond_with(@messages)
end
end
Here we have added a respond_to call at the class level to indicate that we can
serve both HTML and JSON. We have also added a respond_with call at the
bottom of our show method so that Rails knows what it should turn into JSON
—the search results. Rails makes this very easy for us.
Finally, we’ll add an autocomplete="off" attribute to our input field to prevent
the browser itself from suggesting values as we type:
Download capybara/09/app/views/search/show.html.erb
<form id="search" method="get" action="/search">
<fieldset>
<input type="text" id="query" name="query" autocomplete="off" />
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<input type="submit" value="Search" />
</fieldset>
<ol class="results">
<% @messages.each do |message| %>
<li><%= link_to(message.content, [message.user, message]) %></li>
<% end %>
</ol>
</form>
That’s a lot of code all of a sudden, and it’s high time we ran Cucumber again!
Feature: Search
Scenario: Find messages by content
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I search for "I am"
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
@javascript
Scenario: Find messages by content using auto-search
Given a User has posted the following messages:
| content
|
| I am making dinner |
| I just woke up
|
| I am going to work |
When I enter "I am" in the search field
Then the results should be:
| content
|
| I am making dinner |
| I am going to work |
Tables were not identical (Cucumber::Ast::Table::Different)
./features/step_definitions/search_steps.rb:20
features/search.feature:23
Failing Scenarios:
cucumber features/search.feature:16
2 scenarios (1 failed, 1 passed)
6 steps (1 failed, 5 passed)
0m4.473s
Our first feature is still passing, but our new one testing the Ajax isn’t yet.
The table diffing indicates that the two expected lines did not show up on the
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page. If you were running this in a console with colors enabled, you would
see that the rows I am making dinner and I am going to work are yellow, indicating
that they did not show up on the page.
What’s missing?
It can be a little hard to tell at this point. Opening up the search page in a
browser and doing a little bit of manual testing will help us understand what
is going on here. If the search results do indeed show up in the browser, we
might have to tweak our step definition a little. Before we bring up the search
page, we need to make sure we have something to search for. Cucumber
(using DatabaseCleaner) would have cleaned out any data, so we can’t use
that. And besides, Cucumber uses the test database, whereas the running
server we are about to start will use the development one.
Since we haven’t yet created a user interface for posting messages, let’s stick
some messages in the database manually:
$ bundle exec rails console
u = User.create! :username => "_why"
u.messages.create! :content => "I am making dinner"
u.messages.create! :content => "I just woke up"
u.messages.create! :content => "I am going to work"
Let’s start the application:
$ bundle exec rails server
Now we can open a browser, go to http://localhost:3000/search, and start
to poke around. Try to enter I am in the search field without hitting Enter.
You should see two results show up automatically. The app seems to be behaving as expected. So, why was our scenario failing? The reason for this is
timing.
Dealing with the Asynchronous Nature of Ajax
In our couple of steps, we are typing the search term and then verifying that
we have results in our list. The problem is—we are looking for the results too
soon, before the Ajax query has a chance to complete! As we discussed in
Chapter 9, Dealing with Message Queues and Asynchronous Components, on
page 157, we need to introduce a synchronization point so that we can be sure
the search has completed before we proceed in checking what it has returned.
Luckily, Capybara knows how to deal with this situation in a simple way. If
we add an explicit call to find, passing a CSS selector for a DOM element on
the page that doesn’t yet exist, Capybara will wait a little (50ms) and try again
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Matt says:
The Progressive Enhancement Pattern
When I first started using Cucumber, Capybara’s predecessor Webrat was the new
kid on the testing block. Although using Selenium for full-stack JavaScript testing
was possible with Webrat, it wasn’t easy to set up, and we quickly made a decision:
we would build the first iteration of every feature to work without JavaScript. This
was mainly driven by pragmatism; we could easily use Webrat to test the app through
Rails integration testing stack (similar to how Capybara’s rack mode works), and
these tests ran quickly rather than waiting for a browser to start up.
What happened surprised us. First, we would receive fancy designs from our designers
that could be implemented only with fairly complex JavaScript. Because of our rule,
we had to figure out how to deliver the same behavior using basic HTTP posts and
gets of forms and URLs—no JavaScript. This required us to simplify the designs for
our first iteration. We got a little pushback at first, but we were a tight team, and the
designers quickly caught on, especially when we started shipping these first-iteration
features quickly and reliably. And funnily enough, it turned out that often these
simple HTTP-only versions of the features were actually fine, and the designers decided
we should move onto other stuff, instead of building all that complex JavaScript that
had been implied by their earlier designs.
So, this rule had helped us to do the simple thing. We shipped features and moved
on.
When we did have to add JavaScript, we added it on top of the existing working HTTPonly implementation, and we got another surprise: it was easy! Nearly every time,
because we’d built the server-side infrastructure to a clean, standard pattern, the
JavaScript we needed was clean and simple to write.
This technique is known as progressive enhancement.a
a.
http://en.wikipedia.org/wiki/Progressive_enhancement
until the element appears. If it doesn’t appear after a while (two seconds by
default, though this is configurable), it will raise an exception, causing the
step definition to fail. Let’s add that find:
Download capybara/10/features/step_definitions/search_steps.rb
Then /^the results should be:$/ do |expected_results|
# Wait until a matching element is found on the page
find('ol.results li')
results = [['content']] + page.all('ol.results li').map do |li|
[li.text]
end
expected_results.diff!(results)
end
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This will make the scenario pass, and what’s more—we have covered the
essential parts of the Capybara API. Capybara has more to offer, but it’s
mostly variations of what we have already seen.
15.3 The Capybara API
Even though we have used only four of Capybara’s methods at this point, we
have actually explored the most essential parts already. Let’s take a look at
more of Capybara’s API.
The methods in the Capybara API can be grouped in six categories: navigating,
clicking links and buttons, interacting with forms, querying, finding, and
scoping. The following sections list the most common methods. Make sure
you consult Capybara’s own documentation for more comprehensive details.
Navigating
visit(path)
Navigates to the page at path, issuing a GET request.
Clicking Links and Buttons
click_link(locator)
Finds a link by ID or text and clicks it. This may cause
Capybara to load a new page.
click_button(locator)
Finds a button by ID, text, or value and clicks it. This may
cause Capybara to submit a form.
click_on(locator)
Finds a button or link by ID, text, or value and clicks it.
Interacting with Forms
fill_in(locator, {:with =>
text})
Locates a text field or text area and fills it in with the
given text. The field can be found via its name, ID, or label
text.
choose(locator)
Finds a radio button and marks it as checked. The radio
button can be found via name, ID, or label text.
check(locator)
Finds a checkbox and marks it as checked. The check
box can be found via name, ID, or label text.
uncheck(locator)
Finds a checkbox and marks it as unchecked. The
checkbox can be found via name, ID, or label text.
attach_file(locator, path)
Finds a file field on the page and attaches a file given its
path. The file field can be found via its name, ID, or label
text.
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The Capybara API
select(value, {:from =>
locator})
• 269
Finds a select box on the page and selects a particular
option from it. If the select box is a multiple select, select
can be called multiple times to select more than one
option. The select box can be found via its name, ID, or
label text.
Querying
page.has_css?(css_selector)
page.has_xpath?(xpath_expression)
page.has_button?(locator)
page.has_checked_field?(locator)
page.has_unchecked_field?(locator)
Checks whether an element identified by
CSS or XPath is on the page or inside the
current element.
Checks whether an element identified by
locator is on the page or inside the current
element.
page.has_field?(locator, options = {})
page.has_link?(locator, options = {})
page.has_select?(locator, options = {})
page.has_table?(locator, options = {})
Checks whether the page or current node
has the given text content, ignoring any
HTML tags and normalizing whitespace.
page.has_content?(text)
All of the has_xxx? methods return true or false, and they also have an opposite
has_no_xxx? that can be used to verify the absence of elements.
These has_xxx? and has_no_xxx? methods should always be used in conjunction
with assertions—either using Test::Unit or RSpec. For example, to check that
the page has the text orange juice, you would write the following using
Test::Unit:
assert(page.has_content?("orange juice"))
Or using RSpec:
page.should have_content("orange juice")
Finding
find_field(locator)
Finds a form field on the page.
find_link(locator)
Finds a link on the page.
find(selector)
Finds the first matching element on the page using a CSS
selector or raises an error.
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find(:xpath, selector)
Uses XPath to find the first matching element on the page.
You can tell Capybara to use XPath by default with Capybara.default_selector = :xpath.
all(selector)
Returns all elements (as an Array) matching the given
selector.
A full reference can be found at http://rubydoc.info/github/jnicklas/capybara/master/Capybara/Node/Finders.
All find* methods will poll for a maximum of two seconds until an element is
found before it gives up and raises an exception. At first glance, they might
seem similar to the has_xxx? and has_xxx? Query methods, but the find* methods
do not return true or false. Instead, they return a Capybara::Element object on
which you can invoke methods. For example:
page.find('#main-nav').click_link('Login')
If you are familiar with the jQuery JavaScript library, you will find some
similarities here.
Scoping
within(locator, &block)
within_fieldset(locator, &block)
within_frame(frame_id, &block)
within_table(locator, &block)
Executes the given block for a particular scope on
the page. Finds the first element matching the
given locator and executes the block scoped to
that element.
within_window(handle, &block)
Using scoping can sometimes be useful when we want to click, fill in, query,
or find elements in a specific area of a page. This can help avoid picking the
wrong element if there are several similar elements on the page. For example,
if we had more than one Search button on our page and wanted to make sure
we were clicking the one inside our form with id="search", we could have scoped
it like so:
within('#search') do
click_button('Search')
end
Scoping is a powerful technique, especially for complex pages that have a lot
of markup. For simpler pages you may not need it at all—just search globally
on the page as we did in our Squeaker examples.
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Taking Screenshots
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15.4 Taking Screenshots
Taking a screenshot of the browser when a step fails can help you diagnose
failures quicker. These screenshots can be embedded directly into an HTML
report. The trick is to set up an After hook, as described in Section 8.4, Using
Hooks, on page 147. Try adding the following code to a new file in features/support/screenshots.rb:
Download capybara/11/features/support/screenshots.rb
After('@javascript') do |scenario|
if(scenario.failed?)
page.driver.browser.save_screenshot("html-report/#{scenario.__id__}.png")
embed("#{scenario.__id__}.png", "image/png", "SCREENSHOT")
end
end
We can take screenshots only when there is a browser, which is why we tagged
the hook with @javascript. A hook can receive an optional argument that gives
us a reference to the current scenario object, and we ask it if it’s failed so
that we don’t take screenshots for passing scenarios.
Then we get an access to Selenium’s browser object by calling page.driver.browser.
Keep in mind that it’s only Capybara’s Selenium driver that has a browser
accessor. We’re safe since the tag makes sure this happens only when we’re
running Selenium. We’re calling the save_screenshot method from Selenium to
save the screenshot, and we’re using the scenario object’s __id__ as an identifier
for the image file. (In Ruby, all objects have a unique __id__.)
After saving the object, we are calling the embed method, which takes three
arguments—file_name, mime_type, and label. Cucumber will forward this to the
active formatters, which will embed a reference to the file into the report. It’s
actually only the HTML formatter that will take any action here. The other
formatters will just ignore it.
Let’s make a little change to our code to provoke a failure so we can see the
screenshot. Let’s reverse the results from the search in app/model/message.rb:
Download capybara/11/app/models/message.rb
class Message < ActiveRecord::Base
belongs_to :user
def self.like(content)
content.nil? ? [] : where(['content LIKE ?', "%#{content}%"]).reverse
end
end
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Before we run Cucumber again, we have to create the output folder where
the images will be written:
$ mkdir html-report
Now we can run Cucumber with the HTML formatter:
$ bundle exec cucumber --format html --out html-report/index.html
Try opening the generated HTML file in your browser. You should see a
SCREENSHOT link for one of the two failing scenarios. The other failing scenario doesn’t have a screenshot, since it was running with the headless Rack
driver.
15.5 What We Just Learned
Testing web applications can be done in different ways. How to do it depends
on what programming language your application is written in and whether
it’s using JavaScript and Ajax. Let’s summarize what we’ve covered in this
chapter:
• Capybara has a simple DSL for navigating around URLs, filling in forms
values, and clicking buttons and links.
• Capybara has several drivers—some of them built-in, and some of them
available as separate gems—that allow the same code to automate different
browsers or browser simulators.
• Web applications written in Ruby can use Capybara’s Rack driver to test
functionality without JavaScript or Ajax. This is the fastest possible way
to do an end-to-end test.
• For Ruby/Rack applications, the @javascript tag tells Capybara to use the
Selenium driver to test pages that use JavaScript, allowing you to mix
scenarios that use the faster Rack driver with scenarios that need a
browser.
• Web applications that use Ajax (or that are not based on Ruby/Rack)
cannot be tested with Capybara’s Rack driver, but it’s easy to switch over
to the Selenium driver, which brings up a browser.
• We learned to extract multiple text values from the page using Capybara’s
all method and then compare them with a Gherkin table using diff!.
• The A in Ajax stands for asynchronous, which means you sometimes need
to think about where to put synchronization points into your tests.
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Capybara will wait for Ajax content to appear when you call the find
method.
Try This
Capybara can be used outside of Cucumber too. A handy way to practice
getting to grips with Capybara is to automate some dull repetitive task that
you have to do on the Web, such as filling in timesheets or logging in to your
Internet banking.
Create a plain old Ruby script like this one, and flesh it out with whatever
you’d like it to automate:
Download capybara/try_this/web_robot.rb
require 'capybara/dsl'
Capybara.run_server = false
Capybara.default_driver = :selenium
Capybara.app_host = 'http://www.google.com'
class WebRobot
include Capybara::DSL
def go
visit '/'
# ... etc
puts('press any key to finish')
gets
end
end
WebRobot.new.go
Save that file as web_robot.rb and run it with this:
$ bundle exec ruby web_robot.rb
Now flesh out the robot to do your bidding!
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CHAPTER 16
Testing Command-Line Applications
with Aruba
Command-line applications are the bread and butter of many programming
tasks. Any programmer is familiar with common command-line applications
like ls/dir, cp/copy, and cd. If you are a Linux or OS X user, you probably use
them a lot—ps and kill for process management; grep, sed, and awk for file
manipulation; and so on. Even cucumber is a command-line application.
You have probably written a couple of command-line applications or scripts
yourself. Even a Rake task is an example of a command-line script. A command-line application usually starts its life as a small script, but often it
evolves into a more elaborate program. While many people end up testing the
internal logic of a command-line application with unit tests, it is less common
to test the whole stack of the application by interacting with it as a user would,
through the command-line interface—the user interface of the application.
In this chapter, you’ll learn how a Cucumber plug-in called Aruba lets you
test your own (and other people’s) command-line applications. Before we dive
in, let’s first look at some characteristics that all command-line applications
have in common.
16.1 Simple Interfaces
The beauty of command-line applications is that they all have the same simple
interface, as shown in Figure 16, Command-line applications all use the same
simple interface, on page 277. They can read from standard input (STDIN) and
write to standard output (STDOUT). When something goes wrong, they sometimes
write to standard error (STDERR). In addition to using those three streams,
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Aslak says:
How Aruba Was Born
The Aruba gem was born on the island of Aruba in the Caribbean while David Chelimsky (project lead for RSpec) and I were at a conference called SpeakerConf. Open
source contributors get to go to warm places!
RSpec and Cucumber are both command-line applications themselves, and both
projects have a set of Cucumber tests that their developers use when they’re working
on the code. There were a lot of similarities between the two sets of Cucumber tests,
so we extracted a library of common step definitions and called it Aruba. Both
frameworks now use Aruba for their own acceptance tests.
command-line applications can accept arguments on the command line,
which in Ruby end up in the ARGV constant. Consider the following command:
cp foo.txt bar.txt
Here, the two command-line arguments foo.txt and bar.txt are passed to the cp
command-line application.
When a command-line application is done and exits, it reports how the execution went with an exit status. On Linux and OS X, the exit status is available
in the shell variable named $?. On Windows, it’s available in %ERRORLEVEL%. A
nonzero exit status is used to indicate that something went wrong.
Command-line applications can be written in any programming language,
and they can be combined with pipes, like Lego, to perform more advanced
tasks.
Seen from the outside, all command-line applications are the same. The only
way to interact with them is via streams and command-line arguments. This
also means that as far as Cucumber is concerned, the approach for interacting
with a command-line application is the same regardless of what the application
does or what programming language it’s written in. Because the high-level
interaction is the same for all command-line applications, there is no need
to reinvent the wheel every time we want to test a new command-line application. Aruba has everything we need.
16.2 Our First Aruba Feature
Aruba is a Ruby gem that bundles several useful Cucumber step definitions
that you can use in your own scenarios. To stay focused on what Aruba has
to offer, we’re not going to build our own command-line application right now.
Instead, we’ll just use Aruba to test the ruby command-line application. We’re
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STDIN
ARGV
• 277
STDOUT
Command Line
Application
STDERR
Exit status
Figure 16—Command-line applications all use the same simple interface.
going to start off by writing our feature without installing the aruba gem. Just
bear with us; you will soon see it in action. Let’s start with something basic.
Streams and Exit Status
The ruby command has a number of handy command-line options. One of
them is the -e option, which lets us execute a one-liner of Ruby code.
Let’s implement a scenario that verifies that the following command works
as expected:
$ ruby -e 'puts "hello"'
We’ll start by creating a simple project structure. Create an empty folder with
a features directory and a single ruby.feature file:
features/
+-- ruby.feature
Add the following code to features/ruby.feature:
Download command_line_applications/01/features/ruby.feature
Feature: ruby -e
Scenario: print something
When I run `ruby -e "puts 'hello'"`
Then it should pass with:
"""
hello
"""
That’s all we need. Let’s run the feature and let Cucumber lead us to the next
step:
Feature: ruby -e
Scenario: print something
When I run ‘ruby -e "puts ’hello’"‘
Then it should pass with:
"""
hello
"""
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1 scenario (1 undefined)
2 steps (2 undefined)
0m0.001s
You can implement step definitions for undefined steps with these snippets:
When /^I run ‘ruby \-e "([^"]*)"‘$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
Then /^it should pass with:$/ do |string|
pending # express the regexp above with the code you wish you had
end
If you want snippets in a different programming language,
just make sure a file with the appropriate file extension
exists where cucumber looks for step definitions.
As usual, Cucumber is trying to be helpful by suggesting step definition
snippets for us. This time, however, we’ll do things a little differently than
usual. Instead of copying those step definition snippets to our own files, we’re
going to install the aruba gem.
Installing Aruba
There is nothing fancy about installing Aruba. First, we will install the gem.
Create a Gemfile like this and then run bundle to install the gems:
Download command_line_applications/02/Gemfile
source :rubygems
group :test do
gem 'cucumber', '1.1.3'
gem 'aruba', '0.4.8'
end
Now that we have Aruba installed, we can tell Cucumber to use it simply by
adding a features/support/aruba.rb file with a single line:
Download command_line_applications/02/features/support/aruba.rb
require 'aruba/cucumber'
This will load and register several step definitions that are packaged inside
the Aruba gem. When we run the feature again, we get a different result:
Feature: ruby -e
Scenario: print something
When I run ‘ruby -e "puts ’hello’"‘
Then it should pass with:
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"""
hello
"""
1 scenario (1 passed)
2 steps (2 passed)
0m0.314s
Wow! The steps no longer show up as undefined; in fact, they’re passing. This
is because Aruba comes bundled with some generic step definitions for testing
command-line applications. It just so happens that the steps we wrote in our
scenario have matched perfectly with a few of those generic step definitions.
Aruba has helped get our scenario up and running in next to no time, without
having to write a single line of Ruby code. Let’s dig a little deeper to find out
how that works.
Examining Aruba’s Step Definitions
When you have a large library of step definitions, especially one provided by
a third-party library like Aruba, it can be useful to ask Cucumber for a complete list of all the step definitions. You can do that using the stepdefs formatter,
like so:
$ cucumber --format stepdefs
What you should see is a long list of step definitions. If you have colors enabled
in your terminal, you’ll see that two of the step definitions are highlighted in
green, indicating that they’ve been used and have passed. Those step definitions are as follows:
/^I run `([^`]*)`$/
Executes the command between the backticks in a child process, waits for it to finish,
and remembers the STDOUT, STDERR, and exit
status.
/^it should (pass|fail) with:$/
Checks that the exit status indicated pass
or fail as expected.
Verifies that the string you passed in
between triple quotes appears in either STDOUT or STDERR.
If either of these checks fail, Aruba raises
an exception, and the step fails.
Let’s try to provoke a failure. Change the feature to say Then it should fail with:
instead of Then it should pass with:. That should give you the following output:
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Feature: ruby -e
Scenario: print something
When I run ‘ruby -e "puts ’hello’"‘
Then it should fail with:
"""
hello
"""
Exit status was 0 which was not expected. Output:
hello
(RSpec::Expectations::ExpectationNotMetError)
features/ruby.feature:4
Failing Scenarios:
cucumber features/ruby.feature:2
1 scenario (1 failed)
2 steps (1 failed, 1 passed)
0m0.313s
We expected the Ruby process to fail, which technically speaking means exiting
with a nonzero exit status. However, ruby executed our simple program quite
perfectly, so Aruba correctly failed our step.
Now that you understand the fundamentals of how Aruba and Cucumber
work together to test command-line tools, we’ll look at how to work with files.
Try This
Change the feature back to the original Then it should pass with: step.
• Can you make the test fail by changing the Ruby command to produce a
nonzero exit status?
• What happens if you change the expected output to something different
from hello, for example bonjour?
16.3 Working with Files and Executables
Command-line applications often deal with files on the file system. The most
trivial example is the cat command (type on Windows), which prints the contents
of a file to STDOUT. Command-line applications will read files, and sometimes
they’ll write them too. So when we test them, we need to be able to create
files or examine their contents as part of our scenarios.
Remember way back at the beginning of the book in Chapter 2, First Taste,
on page 11 where we created a simple command-line calculator? We’re going
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What If I Care Only About the Exit Status?
The Then /^it should pass with:$/ step definition looks for output in both STDOUT and STDERR
and then looks at exitstatus. While this is a common use case to want to make all these
checks at once, there are situations where we want to check only one or the other,
but not both.
The following step definitions let you do just that:
• /^the exit status should be (\d+)$/
• /^the exit status should not be (\d+)$/
• /^the stdout should contain "([^"]*)"$/
• /^the stderr should contain "([^"]*)"$/
• /^the stdout should not contain "([^"]*)"$/
• /^the stderr should not contain "([^"]*)"$/
to revisit that example now, this time using Aruba to take care of interacting
with the calculator. We’ll build a slightly different calculator that uses a file
as input this time so that we can show you more of Aruba’s features. By using
Aruba, we’ll be able to keep our step definition code from getting too complex
and focus on the behavior we want from the calculator instead.
Create a new project, and we’ll start again from scratch with the feature we
wrote for adding two numbers together:
Download command_line_applications/05/features/adding.feature
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
When the calculator is run
Then the output should be "4"
Of course, we didn’t know about Aruba when we wrote this scenario, so we’re
not going to match any of Aruba’s step definitions. We could reword the scenario to use steps that Aruba understands, but that would make the scenario
harder to read. Instead, we’ll start by using Cucumber’s built-in steps method
to delegate the work to Aruba from the body of our step definitions. Later we’ll
show you how to refactor the step definitions to call Aruba’s Ruby API directly,
but this is a nice simple first step.
First, add Aruba to the project just as before by creating a Gemfile and a file
features/support/aruba.rb with just a single line:
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Download command_line_applications/05/Gemfile
source :rubygems
group :test do
gem 'cucumber', '1.1.3'
gem 'aruba', '0.4.8'
end
Download command_line_applications/05/features/support/aruba.rb
require 'aruba/cucumber'
As usual, run bundle to install the gems if you haven’t already.
Now, run cucumber to get the stub step definition snippets and paste them into
features/step_definitions/calculator_steps.rb. Let’s implement the first step by delegating
to an Aruba step definition:
Download command_line_applications/05/features/step_definitions/calculator_steps.rb
Given /^the input "([^"]*)"$/ do |input|
steps %{
Given a file named "input.txt" with:
"""
#{input}
"""
}
end
We’re using steps inside our step definition to give Cucumber some more
Gherkin to execute, as was first described in Section 5.4, Nesting Steps, on
page 75. We could have written this Gherkin inline in our scenario, but it
would have been coupling our calculator features to be relevant only to the
command-line version. We have big plans for our calculator, so our stakeholders have asked us to try to keep our feature abstract from the nitty-gritty
details of interacting with this particular version. Let’s carry on and implement
the rest of the step definitions using the same pattern:
Download command_line_applications/05/features/step_definitions/calculator_steps.rb
When /^the calculator is run$/ do
steps %{
When I run `ruby calculator.rb input.txt`
}
end
Then /^the output should be "([^"]*)"$/ do |output|
steps %{
Then it should pass with:
"""
#{output}
"""
}
end
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With all that done, let’s run our scenario. We know it’s going to fail because
we don’t have our calculator.rb program in place yet, but it will be useful to get
some feedback nonetheless:
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
When the calculator is run
Then the output should be "4"
Exit status was 1 but expected it to be 0. Output:
/usr/bin/ruby: No such file or
directory – calculator.rb (LoadError)
(RSpec::Expectations::ExpectationNotMetError)
features/adding.feature:6
Failing Scenarios:
cucumber features/adding.feature:3
1 scenario (1 failed)
3 steps (1 failed, 2 passed)
0m0.191s
Out first two steps are passing already, but the last one is failing. The Aruba
step definition we’ve called is checking the exit status of our process. We told
Aruba to expect the process to pass, but it’s found an exit code of 1, indicating
that it failed. As part of the error message, Aruba has printed the output
generated by running the command, which seems to indicate that our calculator.rb program could not be found. That makes sense, since we haven’t added
it yet.
Let’s add the calculator program, putting it in the root of our project as we
did before. Here’s a reminder of what that file should look like:
Download command_line_applications/06/calculator.rb
input = File.read(ARGV[0])
numbers_to_add = input.split('+').map { |n| n.to_i }
total = 0
numbers_to_add.each do |number|
total += number
end
print(total)
When you’ve added that file, your project should look like this:
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calculator.rb
features/
+-- adding.feature
+-- step_definitions
+-- calculator_steps.rb
+-- support/
+-- aruba.rb
Even now, with calculator.rb in place, you’ll still get the same error: Aruba just
can’t see our calculator.rb file. We need some more clues as to what’s going on.
Fortunately, Aruba has a mechanism to help us out.
Using @announce to See What Aruba Sees
Aruba gives you a quick and easy way to see exactly what’s happening as it
interacts with your command-line application. All you have to do is tag the
scenario with @announce, and Aruba will ask Cucumber to report everything
that goes on. Let’s give it a try. Open features/adding.feature and add an @announce
tag at the top of the file. Now run cucumber again. Here’s what you should see:
@announce
Feature: Adding
Scenario: Add two numbers
# features/adding.feature:4
Given the input "2+2"
# features/step_definitions/calculator_steps.rb:2
When the calculator is run
# features/step_definitions/calculator_steps.rb:13
$ cd ~/command_line_applications/06/tmp/aruba
$ /usr/bin/ruby calculator.rb input.txt
/usr/bin/ruby: No such file or directory – calculator.rb (LoadError)
Then the output should be "4" # features/step_definitions/calculator_steps.rb:19
/usr/bin/ruby: No such file or directory – calculator.rb (LoadError)
/usr/bin/ruby: No such file or directory – calculator.rb (LoadError)
Exit status was 1 but expected it to be 0. Output:
/usr/bin/ruby: No such file or
directory – calculator.rb (LoadError)
(RSpec::Expectations::ExpectationNotMetError)
features/adding.feature:7
Failing Scenarios:
cucumber features/adding.feature:4 # Scenario: Add two numbers
1 scenario (1 failed)
3 steps (1 failed, 2 passed)
0m0.118s
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Now we can see each of the commands that Aruba has run and the response
(in this case, in the STDERR stream) from running each command. The first
thing that happened was a cd command, changing the directory into tmp/aruba.
No wonder our calculator.rb program can’t be found: we’re in the wrong directory!
This illustrates an important difference about how Aruba executes commands
compared to the hand-rolled way we did it in Chapter 2, First Taste, on page
11, which we’d better explain.
Isolating Scenarios
When you’re testing a command-line application, files on disk are like
databases. Just as when we test database-driven applications, we want to
avoid state leaking between scenarios, so Aruba provides for this by running
each scenario in a temporary directory. The temporary directory is deleted at
the beginning of each scenario so that it starts with a clean slate. A happy
benefit of cleaning the slate at the beginning rather than the end of a scenario
is that you can examine the files and do a post-mortem if you need to debug
your scenario. Take a look for yourself: you’ll find a tmp/aruba directory in the
root of your project:
$ ls tmp/aruba
You should see the input.txt file that was written the last time you ran your
scenario. If we add another scenario to our feature that also writes to input.txt,
we can be confident that we’ll get a fresh copy of the file for that scenario.
Telling Aruba to Leave Files Alone
By default, Aruba will clear the contents of the tmp/aruba directory before each
scenario. If, for some reason, you want a particular scenario to run but leave
the files on disk alone, you can tag it with @no-clobber. This is often used when
you want to run Aruba in a large, complex folder structure that you’re confident won’t be modified during the scenario.
In that situation, it’s often also useful to tell Aruba to run its tests in a different
directory.
Setting Aruba’s Working Directory
You can tell Aruba to work in a specific directory other than the default
tmp/aruba by setting the @dirs instance variable at the beginning of each scenario.
The best way to do that is in a Before block:
Before { @dirs = ['path/to/somewhere/else'] }
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Aruba Logging
Sometimes it can be handy to see exactly what command Aruba executes and what
the actual output of that command is. This is easily enabled by adding a tag to your
scenario or feature. The tags that Aruba understands are as follows:
@announce-cmd
prints the executed command
@announce-stdout
prints the STDOUT of the executed command
@announce-stderr
prints the STDERR of the executed command
@announce
all of the above
It’s tempting to think about changing the working directory to point to the
root of our project, but we’d also need to set @no-clobber to keep Aruba from
destroying the rest of our source code! What else can we do?
A quick hack to make our scenario work is to specify the full path to calculator.rb.
We can work it out in the step definition relative to that file:
Download command_line_applications/07/features/step_definitions/calculator_steps.rb
When /^the calculator is run$/ do
path = File.expand_path("#{File.dirname(__FILE__)}/../../calculator.rb")
steps %{
When I run `ruby #{path} input.txt`
}
end
But this is a rather ugly solution: previously this step definition was just a
simple Gherkin to Gherkin delegator; now it has Ruby code all mixed up in
there too. When we use steps to delegate to other Gherkin steps, we like to
make sure that it is the only code in the step definition so it stays at the same
level of abstraction throughout, making it easy to read.
Still, it should have made our scenario pass:
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
When the calculator is run
Then the output should be "4"
#
#
#
#
features/adding.feature:3
features/step_definitions/calculator_steps.rb:1
features/step_definitions/calculator_steps.rb:11
features/step_definitions/calculator_steps.rb:19
1 scenario (1 passed)
3 steps (3 passed)
0m0.316s
Great. It’s good to have our scenario working. We’ve removed the @announce
tag since we don’t need the debugging information anymore now that the
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scenario is passing. Now we’ll make our program into a proper binary command so that we can clean up that ugly code in the step definition.
Setting $PATH
What we’d really like is for the calculator to be a full-grown command-line
application with its own binary command. That way, we’ll be able to distribute
it as a Ruby gem, so it will be easy for our users to install and upgrade it.
Creating an actual Ruby gem is out of the scope of this book, but we’ll use
the same conventional structure. First, we need to create a bin directory in
the root of our project.
$ mkdir bin
Now move the calculator.rb file into the bin directory, then rename it to simply
calculator:
$ mv calculator.rb bin/calculator
We need to add a shebang to the file so that the operating system knows that
it’s a Ruby program:
Download command_line_applications/08/bin/calculator
#!/usr/bin/env ruby
input = File.read(ARGV[0])
numbers_to_add = input.split('+').map { |n| n.to_i }
total = 0
numbers_to_add.each do |number|
total += number
end
print(total)
Finally, we need to tell the operating system that the file is executable:
$ chmod +x bin/calculator
At this point, you should be able to run the calculator command manually.
You’ll still need to provide an input file and provide the path to the calculator
command, like this:
$ bin/calculator input.txt
If we were to go through all the steps to turn this into a Ruby gem and install
it on a user’s machine, the bin directory will be added to the operating system
path so that the calculator command can be run from any directory. Let’s simulate that situation in our tests and modify the step definition to call our new
command:
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Special note for Windows Users
On Windows you can’t make a script without a file extension executable. What we
can do instead is create a .bat script that will run our Ruby script. Create a bin/calculator.bat file with the following content:
Download command_line_applications/08/bin/calculator.bat
@"ruby.exe" "%~dpn0" %*
The %~dpn0 will automatically expand to the full path of the .bat script—without the
.bat extension, and that’s our Ruby script. In the examples that follow, make sure you
use the calculator.bat filename instead of calculator so that Windows executes your .bat
file.
If you are developing a Ruby gem, a similar .bat file will be generated automatically
by Rubygems when the gem is installed on Windows.
Download command_line_applications/08/features/step_definitions/calculator_steps.rb
When /^the calculator is run$/ do
steps %{
When I run `calculator input.txt`
}
end
Aruba will automatically add the project’s bin directory to the PATH while the
tests execute, so we don’t need to do anything else. Our scenario should be
passing again:
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
When the calculator is run
Then the output should be "4"
#
#
#
#
features/adding.feature:3
features/step_definitions/calculator_steps.rb:1
features/step_definitions/calculator_steps.rb:11
features/step_definitions/calculator_steps.rb:18
1 scenario (1 passed)
3 steps (3 passed)
0m0.316s
You’ll find many more step definitions in Aruba for working with files and
executables, but now you have a good idea of the fundamentals. Another
common use case for command-line applications is where the user is asked
for input—to enter a password, for example—and that’s what we’ll see next.
16.4 Interacting with User Input
Sometimes a command-line application needs to ask the user a question.
Aruba supports this, allowing you to write scenarios that include a user
responding to requests for information from the command-line application.
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We’ve been getting feedback from user testing of our calculator that a significant number of our users want to be able to perform additions without saving
them to a file first. Let’s write another scenario to describe that use case:
Download command_line_applications/09/features/adding.feature
Scenario: Add two numbers interactively
When the calculator is run with no input
And I enter the calculation "2+2"
Then the output should be "4"
Run cucumber to generate the new step definition snippets, and then paste
them into features/step_definitions/calculator_steps.rb:
Download command_line_applications/09/features/step_definitions/calculator_steps.rb
When /^the calculator is run with no input$/ do
pending # express the regexp above with the code you wish you had
end
When /^I enter the calculation "([^"]*)"$/ do |arg1|
pending # express the regexp above with the code you wish you had
end
We’ll implement the first step definition by delegating to a variation of the
Aruba step definition we used earlier. This time, we’ll tell Aruba we’re going
to interact with the child process:
Download command_line_applications/10/features/step_definitions/calculator_steps.rb
When /^the calculator is run with no input$/ do
steps %{
When I run `calculator` interactively
}
end
When /^I enter the calculation "([^"]*)"$/ do |calculation|
steps %{
When I type "#{calculation}"
}
end
We’ve used two new Aruba step definitions here. You can probably guess how
they work, but let’s explain them:
/^I run `([^`]*)` interactively$/
Executes the command between the
backticks in a child process and connects
to the STDIN, STDOUT, and STDERR streams,
ready for subsequent steps to interact with
the child process.
/^I type "([^"]*)"$/
Sends the given text to the running process’ STDIN stream.
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Run cucumber, and you should have a failing test, ready to drive out our new
behavior:
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
When the calculator is run
Then the output should be "4"
Scenario: Add two numbers interactively
When the calculator is run with no input
And I enter the calculation "2+2"
Then the output should be "4"
Exit status was 1 but expected it to be 0. Output:
~/command_line_applications/10/bin/calculator:2:in
‘read’: can’t convert nil into String (TypeError)
from
~/command_line_applications/10/bin/calculator:2:in
‘<main>’
(RSpec::Expectations::ExpectationNotMetError)
features/adding.feature:12
Failing Scenarios:
cucumber features/adding.feature:9
2 scenarios (1 failed, 1 passed)
6 steps (1 failed, 5 passed)
0m0.638s
We’ve had an error from line 2 of our calculator program, where we try to
read the contents of the input file passed as a command-line argument. That’s
because we haven’t changed our application to wait for user input yet, so it’s
still expecting to be told what file to read. We need to change our calculator
program to ask for input if no file is specified:
Download command_line_applications/11/bin/calculator
#!/usr/bin/env ruby
input = if ARGV.any?
File.read(ARGV[0])
else
puts "Please enter the calculation you'd like me to perform"
gets
end
numbers_to_add = input.split('+').map { |n| n.to_i }
total = 0
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Using Aruba’s Ruby DSL
• 291
numbers_to_add.each do |number|
total += number
end
print(total)
Now if there are no command-line arguments, our calculator will ask the user
to enter the calculation and then sit and wait for them to type something.
Let’s see how this plays out when we run our scenario:
Feature: Adding
Scenario: Add two numbers
Given the input "2+2"
When the calculator is run
Then the output should be "4"
Scenario: Add two numbers interactively
When the calculator is run with no input
And I enter the calculation "2+2"
Then the output should be "4"
2 scenarios (2 passed)
6 steps (6 passed)
0m1.065s
Excellent! We’ve modified the calculator, and not only is our new scenario
passing, but so is the first one, which means we haven’t broken the existing
behavior. Let’s make one last change and refactor our step definitions to make
them even cleaner. Instead of delegating to Aruba’s step definitions, let’s use
the Aruba API directly.
16.5 Using Aruba’s Ruby DSL
Aruba’s step definitions are a great example of how step definitions should
be written. Each of them is hardly ever more than a single line long, delegating
all its work to Ruby methods in Aruba’s support layer module Aruba::API. We
can call these methods directly from our own step definitions, removing an
unnecessary layer of indirection in our code. Here’s how the features/step_definitions/calculator_steps.rb file looks with each of the Aruba step definitions translated
to their underlying method calls:
Download command_line_applications/12/features/step_definitions/calculator_steps.rb
Given /^the input "([^"]*)"$/ do |input|
write_file 'input.txt', input
end
When /^the calculator is run$/ do
run 'calculator input.txt'
end
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• Chapter 16. Testing Command-Line Applications with Aruba
When /^the calculator is run with no input$/ do
run_interactive 'calculator'
end
When /^I enter the calculation "([^"]*)"$/ do |calculation|
type calculation
end
Then /^the output should be "([^"]*)"$/ do |output|
assert_passing_with output
end
Run cucumber, and you should see the feature is still passing just as before.
We find this preferable to leaving the calls to steps in our step definitions. Once
we’re down into the step definitions layer, we like to keep things simple and
work in pure Ruby rather than mixing Gherkin and Ruby together.
16.6 What We Just Learned
With these few examples, you should know enough to start automating tests
for your own command-line applications. Let’s review what we have learned:
• Command-line applications all look the same from the outside, whatever
language they’re written in.
• We can verify that a command-line application prints what we expect it
to print.
• We know how to check that a command-line application exits with a
specific exit status.
• You can create temporary files that the command-line application you
are testing can use.
• Aruba uses an empty, temporary directory for each scenario.
• Aruba recognizes special tags that let us see more informative output.
• We can use Aruba to interact with simple command-line applications that
ask for user input.
We haven’t been through every single step definition of Aruba in this chapter,
but we have shown you the most important ones. If you want to learn more
about the step definitions we haven’t covered, the best place to look is Aruba’s
own Cucumber features on GitHub.1 They provide examples of how to use
Aruba.
Aruba’s built-in step definitions provide a useful starting point for testing
your own command applications, but you shouldn’t let them have too much
1.
http://github.com/cucumber/aruba/tree/master/features
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What We Just Learned
• 293
influence on how you write your scenarios. Make sure that your scenarios
are written in your project’s domain language so that they make the most
sense to you and your team.
Try This
Create your own simple command-line application: a script that takes all its
command-line arguments, changes them to uppercase, and prints them to a
file called result.txt.
Verify that the file result.txt contains the arguments you passed on the command
line, all in uppercase. You should be able to do that using only Aruba step
definitions, without writing a single step definition yourself.
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APPENDIX 1
Using Cucumber with Other Platforms
Although Cucumber started as a Ruby tool, it has grown to embrace many
other platforms. This means you’re able to write your Cucumber step definitions in the same language you use for your production code and reach directly
into your domain model if necessary. Explaining in detail how to use Cucumber to drive all of those platforms is beyond the scope of this book, but this
appendix should give you some pointers where to look for more information.
Platform
Tool
Further Information
iOS
Frank
https://github.com/moredip/Frank
Flash/ActionScript
Cuke4AS3
https://github.com/flashquartermaster/
Cuke4AS3
PHP
Cuke4PHP
https://github.com/olbrich/cuke4php
JavaScript/Node.js
cucumber-js
https://github.com/cucumber/cucumber-js
Java and other JVM
languages
cucumber-jvm
https://github.com/cucumber/cucumber-jvm
Microsoft .NET/Mono
SpecFlow
http://specflow.org/
C++
CukeBins
https://github.com/paoloambrosio/
cukebins
If you’re interested in understanding how these tools work or writing your
own, you could look further into two main things: the Gherkin parser and
the wire protocol.
Gherkin is the language you use to write Cucumber specifications, and it’s
also a library1 you can use to parse them. It uses Ragel2 to generate its code.
1.
2.
https://github.com/cucumber/gherkin
http://www.complang.org/ragel/
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296
• Appendix 1. Using Cucumber with Other Platforms
At the time of writing, the Gherkin parser is released for the following
platforms:
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Appendix 1. Using Cucumber with Other Platforms
• 297
• Ruby 1.8.6-1.9.3 (MRI, JRuby, REE, Rubinius)
• Pure Java (JAR file)
• JavaScript (NPM package; tested with V8/node.js/Chrome, but might
work on other JavaScript engines)
• .NET (DLL file)
This allows you to build your own version of Cucumber on top of any of those
platforms, and that’s how Cucumber-JVM, Cucumber-JS, and SpecFlow all
work.
The second piece of the puzzle is Cucumber’s wire protocol. This allows
Cucumber to invoke step definitions running in another process through a
TCP socket. That process could be running on any machine and be written
in any language. As we write this, Cuke4PHP and Cuke4AS3 are the main
users of the wire protocol, allowing developers to write step definitions in PHP
and ActionScript, respectively, and invoke them from Cucumber itself.
Cucumber’s wire protocol is well documented, with examples, in Cucumber’s
own features. See the Cucumber source code for details.
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APPENDIX 2
Installing Cucumber
A2.1 Installing Ruby
Before you can install Cucumber, you need to install Ruby. The code in this
book was tested with ruby 1.9.3-p0, and we recommend you use this version
or a more recent one. Each operating system has different ways to install
Ruby. This section walks you through the most common installation procedures for OS X, Linux, and Windows.
OS X and Linux
First, you are going to need GCC installed to build Ruby and gems that use
C extensions, including Cucumber. On OS X you will have to install Xcode.
Each Mac ships with a DVD that contains Xcode, and it can also be downloaded from http://developer.apple.com/xcode/.
Some Linux distributions come with GCC pre-installed, but many (such as
Ubuntu) do not. Just to be on the safe side, Linux users should install some
packages. The following commands should work on Ubuntu and other Debian
distributions:
$ sudo apt-get install build-essential curl zlib1g-dev libreadline5-dev
$ sudo apt-get install libssl-dev libxml2-dev libxslt-dev sqlite3 libsqlite3-dev
That will install GCC and some other tools you’ll need to build Ruby and the
various gems used in the book. You should now be ready to install RVM.
We recommend you use RVM (Ruby Version Manager) to install Ruby. RVM
is a command-line tool that allows you to easily install, manage, and work
with multiple Ruby environments from interpreters to sets of gems. That
means that even if you already have another version of Ruby installed, you
can use the same one as these code examples have been tested with.
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300
• Appendix 2. Installing Cucumber
To install and use RVM, you’ll first need to install Git, which you can download
from http://git-scm.com/download. On Ubuntu you can install Git with sudo
apt-get install git-core.
Follow
the
installation
instructions
on
the
RVM
website
(http://beginrescueend.com/). Make sure to follow the post-installation instructions—including restarting your terminal—to set up a simple rvm command you can run from a shell. When you have installed RVM, use it to install
Ruby 1.9.3-p0 and make that your default Ruby interpreter:
$ rvm install ruby-1.9.3-p0
$ rvm --default ruby-1.9.3-p0
Windows
We recommend you use Ruby Installer to install Ruby on Windows. You can
get it from http://rubyinstaller.org/.
You’ll then need to install the Ruby Installer Development Kit after you have
installed Ruby. This installs a GCC compiler tool chain that will allow you to
install gems that use C extensions later. (You cannot use Visual Studio for
this.) You can get the Ruby Installer Development Kit from http://rubyinstaller.org/add-ons/devkit/.
If you have any problems during installation, please refer to the troubleshooting page for Ruby Installer: https://github.com/oneclick/rubyinstaller/wiki/
Troubleshooting.
Console Colors on Windows
Cucumber uses ANSI escape codes to print colored output to the console.
This isn’t supported natively in Windows, so you have to install a tool called
ANSICON to see colors.
Download and unzip the latest version from https://github.com/adoxa/ansicon/downloads. Open a command prompt and cd to the folder where you
unzipped it. Now, cd into either x86 or x64 (depending on your machine’s processor) and install it globally on your machine:
C:\somewhere\ansi140\x64> ansicon -i
Any program that prints ANSI colors will now display properly on your
machine.
A2.2 HTTP Proxy Settings
If you are behind a corporate firewall or HTTP proxy, you may have to tell
RubyGems how to get through it so it can download gems from the Internet.
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Installing Bundler
• 301
This can be done by defining the environment variable HTTP_PROXY=http://
user:pass@host:port.
A2.3 Installing Bundler
Bundler is a tool that makes it easier to keep track of what gems (and what
versions of those gems) an application depends upon. It does so by installing
all the gems in your application’s Gemfile. All of the code examples in this book
use a Gemfile.
Bundler itself is a gem and can be installed with the following:
$ gem install bundler
A2.4 Installing Cucumber (and RSpec)
Cucumber is packaged as a gem and can be installed by running gem install
cucumber. However, most of the examples in this book assume you install it
via Bundler, which means having a Gemfile in the root directory of your project.
Most of the examples also assume you’ll use RSpec,1 so you’ll need that in
your Gemfile too:
Download installation/Gemfile
source :rubygems
group :test do
gem 'cucumber', '1.1.3'
gem 'rspec-expectations', '2.7.0'
end
Cucumber will then install with the following command:
$ bundle install
To verify that you have installed it properly, run cucumber --help.
A2.5 Installing Other Gems
Various chapters in this book uses other gems, such as rails or capybara. These
are installed by adding them to your Gemfile and running bundle update. In most
places, we will list what you need to put in your Gemfile, and you can always
find the Gemfile by downloading an example’s source.
If you just want to install a complete set of all the gems used in the book in
one go, you can use the master Gemfile listed in Appendix 3, Ruby Gem Versions, on page 303.
1.
http://rubygems.org/gems/rspec
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302
• Appendix 2. Installing Cucumber
A2.6 Choosing a Text Editor
You can use any text editor to work with Cucumber. If you don’t have a favorite
editor, we recommend one of the following free ones:
• Windows: Notepad++: http://notepad-plus-plus.org/
• OS X: TextWrangler http://www.barebones.com/products/TextWrangler/
• Linux: GEdit: http://projects.gnome.org/gedit/
All of these editors have plug-ins or extensions that will syntax highlight
Cucumber’s feature files.
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APPENDIX 3
Ruby Gem Versions
This book uses several Ruby gems for the code examples. Things move
quickly in the open source world, and the versions of many of the gems we’ve
used will have been superseded by the time you read this. You’ll find the code
examples will work best if you use the same versions of the gems as we did,
so there’s a complete list of them in this appendix.
To install these gems, create a working directory where you’ll be writing the
code examples, and download this Gemfile:
Download Gemfile
# This Gemfile lists all Gems used throughout the book - with versions.
source :rubygems
# Build stuff
gem 'bundler', '1.0.21'
gem 'rake', '0.9.2.2'
gem 'watchr', '0.7'
gem 'bcat', '0.6.2'
# General stuff
gem 'aruba', '0.4.8'
gem 'cucumber', '1.1.3'
gem 'rake', '0.9.2.2'
gem 'rspec', '2.7.0'
# Rails stuff
gem 'activerecord', '3.1.3'
gem 'capybara', '1.1.2'
gem 'coffee-rails', '3.1.1'
gem 'cucumber-rails', '1.2.1'
gem 'database_cleaner', '0.7.0'
gem 'factory_girl', '2.3.2'
gem 'jquery-rails', '1.0.19'
gem 'launchy', '2.0.5'
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304
• Appendix 3. Ruby Gem Versions
gem
gem
gem
gem
gem
'rails', '3.1.3'
'rspec-rails', '2.7.0'
'sass-rails', '3.1.5'
'sqlite3', '1.3.5'
'uglifier', '1.1.0'
# Non Rails stuff
gem 'childprocess', '0.2.3'
gem 'httparty', '0.8.1'
gem 'json', '1.6.3'
gem 'rack-test', '0.6.1'
gem 'service_manager', '0.6.2'
gem 'sinatra', '1.3.1'
Now, once you’ve followed the instructions in Appendix 2, Installing Cucumber,
on page 299, you can run the bundle command in the directory where you saved
the Gemfile, and exactly the right versions of all the gems should install on
your machine.
To ensure that these gem versions don’t clash with other gems on your
machine, we recommend either using a feature of RVM called gemsets1 or
prefixing all commands with bundle exec. For example, to run cucumber, you’d
run this:
$ bundle exec cucumber
That way, you’ll ensure that Bundler picks the right set of gem versions using
your Gemfile and ignores any other versions you may have already installed
on your machine.
1.
http://beginrescueend.com/gemsets/
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APPENDIX 4
Bibliography
[Adz11]
Gojko Adzic. Specification by Example. Manning Publications Co., Greenwich, CT, 2011.
[And10]
David J. Anderson. Kanban. Blue Hole Press, http://www.e-junkie.com/
129573, 2010.
[Bec00]
Kent Beck. Extreme Programming Explained: Embrace Change. AddisonWesley Longman, Reading, MA, 2000.
[Bec02]
Kent Beck. Test Driven Development: By Example. Addison-Wesley, Reading,
MA, 2002.
[Bro95]
Frederick P. Brooks Jr.. The Mythical Man Month: Essays on Software Engineering. Addison-Wesley, Reading, MA, Anniversary, 1995.
[CADH09] David Chelimsky, Dave Astels, Zach Dennis, Aslak Hellesøy, Bryan
Helmkamp, and Dan North. The RSpec Book. The Pragmatic Bookshelf,
Raleigh, NC and Dallas, TX, 2009.
[CG08]
Lisa Crispin and Janet Gregory. Agile Testing: A Practical Guide for Testers
and Agile Teams. Addison-Wesley, Reading, MA, 2008.
[Coc04]
Alistair Cockburn. Crystal Clear: A Human-Powered Methodology for Small
Teams. Addison-Wesley Professional, Boston, MA, 2004.
[Coh05]
Mike Cohn. Agile Estimating and Planning. Prentice Hall, Englewood Cliffs,
NJ, 2005.
[Dee08]
Ian Dees. Scripted GUI Testing with Ruby. The Pragmatic Bookshelf, Raleigh,
NC and Dallas, TX, 2008.
[Eva03]
Eric Evans. Domain-Driven Design: Tackling Complexity in the Heart of
Software. Addison-Wesley Longman, Reading, MA, First, 2003.
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306
• Appendix 4. Bibliography
[FBBO99] Martin Fowler, Kent Beck, John Brant, William Opdyke, and Don Roberts.
Refactoring: Improving the Design of Existing Code. Addison-Wesley, Reading,
MA, 1999.
[FP09]
Steve Freeman and Nat Pryce. Growing Object-Oriented Software, Guided
by Tests. Addison-Wesley Longman, Reading, MA, 2009.
[Fea04]
Michael Feathers. Working Effectively with Legacy Code. Prentice Hall,
Englewood Cliffs, NJ, 2004.
[HT00]
Andrew Hunt and David Thomas. The Pragmatic Programmer: From Journeyman to Master. Addison-Wesley, Reading, MA, 2000.
[Joh10]
Christian Johansen. Test-Driven JavaScript Development. Addison-Wesley
Professional, Boston, MA, 2010.
[Mar07]
Brian Marick. Everyday Scripting with Ruby. The Pragmatic Bookshelf,
Raleigh, NC and Dallas, TX, 2007.
[Mes07]
Gerard Meszaros. xUnit Test Patterns. Addison-Wesley, Reading, MA, 2007.
[Ohn88]
Taiichi Ohno. Toyota Production System - Beyond Large Scale Production.
Productivity Press, New York, NY, USA, 1st, 1988.
[TFH08]
David Thomas, Chad Fowler, and Andrew Hunt. Programming Ruby: The
Pragmatic Programmer’s Guide. The Pragmatic Bookshelf, Raleigh, NC and
Dallas, TX, Third, 2008.
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Index
SYMBOLS
# language: comment, 34
$ anchor, 52, 117
$ character, escaping, 41, 47
$? variable, 17
%{ ... } construct, 76
* keyword, 32
* modifier, 46
+ modifier, 48, 50
- character, 18, 194
. character
progress formatter, 18,
194
wildcard, 46
: notation, 194
? modifier, 51
@ tag, 80
^ anchor, 52, 117
| character, 65
A
abstraction, 92–93, 128
acceptance criteria, 26
acceptance testing
about, 4–5
collaboration and, 5
concrete examples, 27
ActionScript, 295
ActiveRecord
creating records, 234,
237, 248
data builders and, 98
database interfacing,
174–187
database schema management, 102
legacy databases, 175
migration, 102, 174, 176
Adzic, Gojko, 6, 73, 89
After hook, 147, 181, 183,
187, 271
AfterConfiguration hook, 150
AfterStep hook, 150
Agile Testing: A Practical
Guide for Testers and Agile
Teams, 4, 101
Ajax
asynchronicity, 266
searching with, 257–268
alternation, 46, 51
anchors, regular expressions,
52, 117
And keyword, 31
AND statements, 193
@announce tag, 284, 286
ANSI colors, 300
ANSICON, 300
Anticipate gem, 172
app_host, 261
AppHelper, 207
arguments
capturing, 45–50, 117–
120
in command-line applications, 275
multiple captures, 49
nested steps and, 77
transforms, 117–120
ARGV[0], 23
Around hook, 148
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Array
connecting users and
messages, 248
search function, 253
arrays, turning tables into,
67, 217, 248
Aruba
about, 275–276
basic testing, 276–280
calculator application,
280–292
files and executables,
280–288
installing, 278
logging, 286
step definitions, 279,
289, 291
user input, 288–291
ask method, 126, 262
assertions
adding, 19, 115
asynchronous, 172
exceptions and, 55, 57
libraries, 60
Rails, 230
associating messages with
users, 239
asterisk keyword, 32
asynchronous architecture,
157–172, 266
at_exit hook, 150, 166, 217
ATM application
asynchronous architecture, 157–172
back-end architecture,
161–169
Background element, 62–64
balance exercise, 155
308
• Index
database transactions,
175–187
overdraft exercise, 155
PIN authentication and
change, 62–64, 75
teller function, 120–128
user interface, 133, 141–
155
withdrawals, 70–78, 111–
128, 133–137, 152–154
authentication application
examples description, 74
incidental details, 90
PIN, 62–64, 75
autocomplete="off" attribute, 264
automated testing
about, 4
collaboration and, 4–5
concrete examples, 25,
27
legacy applications, 221–
227
maintenance, 105
reliability problems, 97–
104
skills needed, 140
automation libraries, see libraries
B
\b shorthand, 49
back-end services, message
queues, 157, 161–169
Background element, 61–65
--backtrace option, 196
balance exercise, 155
.bat file, 288
BDD (Behaviour-Driven Development), 4
Beck, Kent, 22, 137
Before hook, 147, 183, 212
begin..rescue structure, 171
Behaviour-Driven Development (BDD), 4
Big Ball of Mud, 103–104
booting up, support code, 129
bored stakeholders, 86, 88–
97
brittle features, 86–87
brittle scenarios
coupling, 133
doc strings, 79
duplication and, 22, 93
fixture data, 102
imperative style, 92
leaking states, 97
state and, 32
symptoms, 86–87
tester collaboration, 101
Brooks, Fred, 25
browsers
databases and, 185
screenshots, 200, 271
bugs
defect rate, 228
legacy applications, 224
missing scenarios, 135
naming, 226
Bundler, installing, 301
business stakeholders, see
also collaboration
acceptance testing and,
4–5
bored, 86, 88–97
concrete examples, 26
But keyword, 31
buttons, 268
C
C#, xix
C++, 295
calculator application
Aruba, 280–292
simple, 11–23
capture groups, 45, 119
capturing arguments, 45–50,
117–120
Capybara
about, 245
associating messages
with users, 239–243
custom step definitions,
249
database cleaning, 185
drivers, 245, 259
extracting markup, 253
hooks, 150
methods list, 268–270
non-Ruby applications,
261
pausing, 262
search, Ajax, 257–268
search, simple, 246–257
synchronization, 266
user interface wrapping,
141–146, 150–154
character classes, 47, 49
characterization tests, 222–
225
characters, escaping, 41, 47
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Chemlinsky, David, 276
child process, Aruba interaction, 289
ChildProcess, poor man’s
Service Manager, 166
Chisolm, Josh, 172
classes, defining, 113
cleaning databases, 181–187,
212, 230
clicking methods in Capybara, 268
Cockburn, Alistair, 22, 104
code coverage, 227–228
collaboration, see also communication; ubiquitous
language
automated testing and,
4–5
bugs, 135
problems, 88
testers, 101
unit testing, 104
colon in command-line interface, 194
colors, console, 300
combinatorial explosion, 73
command-line applications
about, 275
arguments in, 275
Aruba testing, basic,
276–280
exit status, 276, 281
files and Aruba, 280–288
user input, 288–291
command-line interface, see
also Aruba
continuous integration,
199
filtering, 192–194
location specifying, 196
managing WIP, 197
options list, 191
outputs, 194–196
profiles, 198
Rake, 198
commas, 193
comments, 33, 35
communication, see also collaboration; ubiquitous language
concrete examples, 25
importance of, 3
precision, 26
problems, 89–97
Index
comparing
data vs. strings, 213
tables with diff, 68
concrete examples, 25, 27
conditions of satisfaction, 26
console colors, 300
continuous improvement, 105
continuous integration
command-line options,
199
formatters, 195, 199
strict mode, 57
controllers
creating by hand, 240
search function, 249–
251, 264
converting
markup, 254
strings into numbers,
113, 117–120
coupling, 133, 149
create! method, 248
credit card payment application, 26–28
Crispin, Lisa, 4
Crystal Clear: A Human-Powered Methodology for Small
Teams, 22
CSS selectors, 253, 266
Cucumber
benefits, xvii, 89
example tests, 5
installing, 299–302
layers, 14
non-Ruby platforms, 295
overview, 7
problem symptoms, 85–
89
resources, xx
why use, 3–9
Cucumber-JS, 295
Cucumber-JVM, 295
Cucumber-Rails, see Rails
Cuke4AS3, 295
Cuke4PHP, 295
CukeBins, 295
custom helper methods, 120–
128
CWhildProcess, out-of-process REST testing, 213
D
\d shorthand, 49
DAMP principle, 94
data
builders, 98, 102, 234
fixture, 101, 234
stores, 203, 216
vs. strings, 213
Data tables, 77
data tables, 64–69, 71, 217,
254, see also tables
DatabaseCleaner gem, 182–
185, 230
databases
ActiveRecord, 102, 174–
187, 234, 237, 248
browser testing, 185
cleaning, 181–187, 212,
230
FactoryGirl, 98, 102,
232–235
migrations, 102, 174–
178, 233, 238
one-click systems setup,
102
querying, 252, 256
reading and writing to,
178–181
resetting, 216
setting, 248
shared environments,
100, 102
debugger statements, 262
declarative style, 91–93, 249
defect prevention, 106
defect rate, 228
definitions, step, see step
definitions
Delayed Job, 160
deleting, scenarios, 226
dependencies
avoiding, 32, 97
files, 129
dependency injection, 126
descriptions
Background elements, 63
documentation, 35
examples tables, 74
features, 29, 31
rules, 74
scenarios, 32, 74
Descriptive and Meaningful
Phrases (DAMP), 94
design criteria, 137
details, incidental, 90, 107,
234
diff! method, 68, 254
digit character shorthand, 49
www.it-ebooks.info
• 309
Direct Model Access (DMA),
237
directories
creating, 12
domain model, 129
isolating in Aruba, 285
lib, 129
scanning, 196
@dirs instance variable, 285
discussion forums for Cucumber, xx
DMA (Direct Model Access),
237
doc strings, 78
documentation
comments and descriptions, 35
living, 6, 89, 97
tags, 82
user stories, 81
DOM elements, synchronization, 266
Domain Driven Design, 5
domain model
directory, 129
organizing, 130
sketching, 112–114
user interface wrapping,
133, 141–155
Don’t Repeat Yourself (DRY)
principle, 93–94, see also duplication, avoiding
dot character
progress formatter, 18,
194
wildcard, 46
drivers, Capybara, 245, 259
DRY principle, 93–94, see also duplication, avoiding
--dry-run, 29, 130
DSL module, 146
duplication, avoiding
in ActiveRecord, 234
design criteria, 137, 140
examples tables, 72
steps and examples, 93
transforms, 117–120
walking skeleton, 22
E
-e option, 277
eXtreme Programming, 4
embed method, 271
env.rb file
--dry-run and, 130
310
• Index
booting up, 129
deleting code, 214
Rails, 231
environments, shared, 100,
102
errors, see exceptions
escaping special characters,
41, 47
eval method, 23
Evans, Eric, 5
eventually method, 170, 172
Everyday Scripting with Ruby,
xviii, 163
examples
duplication, 94
key, 73
number of, 73
tables, 71–75
writing, 6, 25, 27
Examples tables, 71–75
exceptions
assertions and, 55, 57
confidence in, 253, 255
external services, 169
failed steps, 56
executable specifications, 6,
27
exit hook, 150, 166, 217
exit status, 276, 281
--expand option, 71
exploratory testing, 101
Extreme Programming Explained, 137
F
F character in progress format-
ter, 18, 194
Factory method, 232
FactoryGirl, 98, 102, 232–235
false positives, 44
façades, 205
Feathers, Michael, 104, 222
Feature Injection template,
31
Feature keyword, 13, 29
features
adding to legacy applications, 225
brittle, 86–87
comments, 33, 35
coupled steps, 149
creating, 12
descriptions, 29, 31
naming, 29, 226
organizing, 79–82, 103
overview, 7
partitioning, 89
sharing, 96
siloed, 95
slow, 86–87, 103
subfolders, 80
synchronization points,
170
templates, 31
feedback
code coverage as, 228
loops, 97
files
Aruba and, 280–288
organizing, 128–131
filtering
lines, 193
names, 194
tags, 82, 193
find, 266, 270
finding methods in Capybara,
270
firewalls, 300
Fixnum integer, 117
fixtures
data, 101, 234
terminology, 99
Flash, 295
flickering scenarios, 86, 99–
100, 102, 159, 165–171
flight code exercise, 48
folders
organizing with, 79–80,
103
partitioning with, 89
formatters
changing, 18, 194–196
HTML, 19, 271
html, 195, 199
json, 195
JUnit, 19
junit, 195, 199
listing, 19
progress, 18, 194
rerun, 195
screenshots, 271
stepdefs, 195, 279
usage, 195
forms, HTML, 150, 268
Fowler, Martin, 94
Frank, 295
Freeman, Steve, 159
www.it-ebooks.info
fruit retrieval application
in-process testing, 202–
212
out-of-process testing,
213–220
G
Gemfile
Bundler installation, 301
creating, 141
versions list, 303
gemsets, 304
generators, Rails, 230–231
get method, 206
GET requests, 208, 210, 252,
261
Gherkin
basics, 25–36
comments, 33, 35
data tables, 64–69
doc strings, 78
format and syntax, 28
imperative style, 91, 93
keywords, 13, 28–31, 43,
45
languages support, 28,
34, 36, 45
nested steps, 75–78
overview, 7
parser, 295
readability, 27
scenario outlines, 70–75
tags, 79–82
Given keyword, 13, 30, 42
goals, features, 31
Gregory, Janet, 4
Growing Object-Oriented Software, Guided by Tests,
137, 159
Guard, 241
H
Hash objects, 248
hashes method, 217
have_content, 242
Helkamp, Bryan, 246
--help, 19, 191
helper methods
custom, 120–128
listing, 124
hierarchy, stack, 7
hooks
After, 147, 181, 183, 187,
271
AfterConfiguration, 150
Index
AfterStep, 150
Around, 148
at_exit, 150, 166, 217
Before, 147, 183, 212
@javascript, 258–261
state, 147, 164
tagged, 82, 147, 149,
258–261
using, 147–150
hostnames, non-Ruby applications, 261
HTML
formatters, 19, 195, 200,
271
forms, 150, 268
HTTP
error responses, 210
HTTParty, 213–214, 219
proxy settings, 300
REST mimicking methods, 205
Hydra, 89
I
--i18 switch, 35
iOS, 295
imperative style, 76, 91, 93
improvement, continuous,
105
in-process testing, 201–212
incidental details, 90, 107,
234
indentation, doc strings, 78
independent scenarios, 98
intention, revealing, 138
isolation
in Aruba, 285
databases and, 184
J
jQuery, auto-search testing,
261–264
jargon, see ubiquitous language
Jasmine, 262
Java, xix, 295
JavaScript, xix
auto-search testing, 258–
268
TDD, 262
tools, 295
Webrat and, 267
@javascript tag, 82, 258–261
Jenkins, 89
JSON
formatters, 195
REST web service testing,
205, 208–212, 216
search function, 261, 264
whitespaces, 211
JUnit, formatters, 19, 195,
199
JVM, xix
K
Keogh, Liz, 31
key examples, 73
keyup event, 264
keywords, Gherkin
* (asterisk), 32
And, 31
Background, 61–64
But, 31
comments, 33
Feature, 13, 29
Given, 13, 30, 42
list, 28, 45
Scenario, 13, 30–31
Scenario Outline, 22, 70–75
structure, 13
Then, 13, 30, 43
When, 13, 30, 43
KnowsTheDomain module, 129–
130
L
language, see also communication; ubiquitous language
concrete examples, 25
Gherkin support, 28, 34,
36, 45
readability, 5, 27, 211
revealing intention, 138
search function, 249
last_response method, 208
@last_response variable, 219
launchy gem, 150
Lawrence, Richard, 149
leaky scenarios, 97, 102
leaning on the compiler, 139
legacy applications
adding new behavior, 225
adding tests to, 221–227
breaking up, 104
bugs, 224
characterization tests,
222–224
code coverage, 227–228
fixture data, 101
lib directory, 129
www.it-ebooks.info
• 311
libraries
about, 40
assertions, 60
Net::Http, 214
overview, 7
testers and, 101
--line option, 193
--lines option, 194
lines, filtering on, 193
links, 268
Linux installation, 299
listening, synchronization by,
159
living documentation, 6, 89,
97
loads and shared environments, 100
location specification, 196
logging, Aruba, 286
M
maintenance, test, 105
markup, extracting, 253
matching
capture groups, 45
RSpec, 124, 242
steps, 40–50, 117
transforms, 117
Matts, Chris, 31
memcache daemons, oneclick systems setup, 102
memory stores, 203, 216
message posting application,
236–243
message queues
one-click systems setup,
102
using, 157–172
metacharacters
$ sign, 41, 47, 52
anchors, 52
dot, 18, 46, 194
escaping, 47
metrics, 228
Microsoft .NET, 295
migrating databases, 174–
178, 233, 238
MiniTest, 60
missing scenarios, 135
missing steps, 199
models, Rails
creating users, 232–235
message posting, 236–
243
312
• Index
modifiers
plural, 51
repetition, 46, 48
modifiers, regular expressions
plus, 48, 50
question mark, 51
star, 46
modules, World, 124, 129–130
Mono, 295
multiple captures, 49
N
--name option, 194
naming
Background elements, 63–
64
bugs, 226
features, 29, 226
filtering by name, 194
lib directory, 129
revealing intention, 138
scenarios, 32, 34
navigating methods in Capybara, 268
negation, 49, 193
nested steps, 75–78
Net::Http library, 214
Nicklas, Jonas, 246
nightly builds, 103
No Silver Bullet, 25
@no-clobber tag, 285
Node.js, 295
noncapturing groups, 51
North, Dan, 94, 149
O
Ohno, Taiichi, 105
one-click system setup, 102
operator, asking the, 126
OR statements, 193
organizing
files, 128–131
step definitions, 130
with tags and sub-folders, 103
with tags and subfolders,
79–82
transforms and modules,
130
OS X installation, 299
--out option, 195
out-of-process testing, 201,
213–220
outputs, changing, 194–196
outside-in development
benefits, xviii, 17
bugs, 135
placeholders, 21
sketching, 115
TDD and, 4
what vs how, 115
overdraft exercise, 155
P
page content verification, 252
page object, 242
pairwise gem, 73
parallel testing, 89, 103
parsing
Gherkin parser, 295
strings, 211, 213
partitioning
features, 89
steps, 129
tests, 103
$PATH, 287
pauses, see sleeps
payroll system application, 98
pending marker, 16
pending steps, 16, 55, 199
Pettichord, Bret, 246
PHP, 295
PID (process identifier) file,
166
PIN authentication, 62–64, 75
pipe character, 65
placeholders, 21, 71
plurals modifier, 51
plus modifier, 48, 50
polling, 160–161
ports and adapters architecture, 104
POST, 216, 252
post, HTML forms, 151
posting Squeaker messages,
236–243
precision, 26, 44
Premdas, Andrew, 77
problems, see also brittle
scenarios
bored stakeholders, 86,
88–97
communication, 89–97
flickering scenarios, 86,
99–100, 159, 165–171
leaky scenarios, 97, 102
race conditions, 99–100
www.it-ebooks.info
reliability, 97–104
root-cause analysis, 105–
106
shared environments,
100, 102
slow features, 86–87, 103
symptoms, 85–89
too many scenarios, 103
process identifier (PID) file,
166
--profile option, 198
profiles, command line, 198
Programming Ruby: The Pragmatic Programmer’s Guide,
xviii, 163
progress formatter, 18, 194
progressive enhancement,
267
proxy settings, 300
Pryce, Nat, 159, 234
puts method, 254
puts self, 124
Q
queries
database, 252, 256
list of Capybara methods,
269
question mark modifier, 51
queues, see message queues
QUnit, 262
R
race conditions, 99–100
Rack
pros and cons, 259
Rack-Test, 205–208
search, simple, 246–257
rackup, 214, 217
Ragel, 295
Rails
building applications,
229–235
creating controllers by
hand, 240
creating users, 232–235
database cleaning, 185
generators, 230–231
message posting, 236–
243
Rake, 198, 231
Rake, 198, 227, 231
rake -T, 227
raw method, 67
Index
readability
collaboration, 5
examples tables, 72–73
need for, 27
REST interfaces, 211
scenarios, 61
ubiquitous language
building, 50
refactoring
Background, 65
long test runs, 88
revealing intention, 138
Refactoring: Improving the
Design of Existing Code,
139
regressions, 116
regular expressions
anchors, 52, 117
avoiding, 42
capturing arguments, 45–
50, 117–120
character classes, 47, 49
matching steps, 40–48
modifiers, 46, 48, 50–51
noncapturing groups, 51
transforms, 117–120
wording flexibility, 50–52
reliability problems, 97–104
Relish, 96
repetition modifiers, 46, 48
repetition, avoiding
Background elements, 64
data tables, 64–69
scenario outlines, 70–75
reports, sharing, 199
--require option, 196, 198
require_relative, 162, 177
rerun formatter, 195
respond_to, 264
REST testing
in-process, 201–212
out-of-process, 213–220
revealing intention, 138
reviewing code, 137–141
robot exercise, 36, 273
root-cause analysis, 105–106
routes, adding, 250
RSpec
Aruba and, 276
assertions, 20, 60, 230
installation, 301
matchers, 124, 242
Rails assertions, 230
REST web service testing,
205
Story Runner, 81
The RSpec Book, 137
RSpec Story Runner, 81
rspec-rails gem, 230
Ruby, see also step definitions
gems list, 303
installing, 299
overview, 7
resources, xviii
version, 299
ruby
Aruba testing, 276–280
options, 277
Ruby Installer Development
Kit, 300
Ruby Version Manager (RVM),
299, 304
ruby-debug19, 262
rules, describing, 74
run times
sleeps and, 100
slow, 87
too many scenarios, 103
RVM (Ruby Version Manager),
299, 304
S
\s shorthand, 49
sampling, synchronization by,
159–160, 169–171
satisfaction, conditions of, 26
scanning directories, 196
Scenario keyword, 13, 30–31
Scenario object, 148
Scenario Outline keyword, 22,
70–75
scenarios, see also brittle
scenarios; hooks
Background, 61–64
bugs, 226
comments, 33, 35
creating, 12–17
data tables, 64–69, 77
deleting, 226
dependent, 97
descriptions, 32, 74
doc strings, 78
example tables, 71–75
execution overview, 52
filtering, 192–194
fixture data and, 102
www.it-ebooks.info
• 313
flickering, 86, 99–100,
102, 159, 165–171
imperative, 76, 91, 93
implementing, 17–23
incidental details, 90,
107
independent, 98
isolating in Aruba, 285
leaky, 97, 102
missing, 135
naming, 32, 34
nested steps, 75–78
nightly builds, 103
outlines, 70–75
overview, 7
placeholders, 21, 71
results states, 52–60
slow features, 86–87, 103
state and, 32, 97, 102,
201
synchronization points,
159, 171
tags, 79–82, 197
Three Amigos, 95–96
too many, 103
translating bugs into,
224
World and, 125
writing, 30–33, 61, 89–97
scoping, 270
screenshots, 200, 271
search
Ajax, 257–268
simple, 246–257
search plug-in, 264
Selenium, 246, 258–268, 271
separation layer, 133
serializing, 162
Service Manager gem, 165–
169, 261
shared environments, 100,
102
sharing
features, 96
reports, 199
shebang, adding, 287
shorthand character classes,
48–49
siloed features, 95
SimpleCov, 227
Sinatra
404 Page Not Found page, 210
about, 206
REST web service testing,
201, 204–212
314
• Index
test doubles, 154
user interface wrapping,
141–146, 150–154
skeleton
REST web services, 203
walking, 22
sketching, 112–114, 253
skills, testing, 140
slave machines, 89
sleeps, 99–100, 168, 171
slow features, 86–87, 103
snippets, 14, 54, 278
source of truth, 7
SpecFlow, 295
special characters, escaping,
41
Specification by Example, 6
specification tests, 222
specifications, executable, 6,
27
splitting, see partitioning
spoken languages support,
28, 34, 36, 45
sqlite3 database, using, 175–
187
Squeaker application
creating users, 232–235
generators, 230–243
message posting, 236–
243
search, Ajax, 257–268
search, simple, 246–257
stack, hierarchy, 7
stakeholders, see business
stakeholders
star modifier, 46
starting web services, 217
state
Background elements and,
64
hooks, 147, 164
in-process testing, 201
independence, 32
leaky scenarios, 97, 102
message queues and, 164
scenarios and, 201
World and, 122
step definitions, see also Aruba
about, 39
capturing arguments, 45–
50
creating, 14–17, 42–45
custom Capybara, 249
data tables, 64–69, 77
doc strings, 78
domain model, 112–114
exit status, 281
failing, 56
global scope, 149
implementing, 16–20
location specifying, 196
matching, 40–50, 117
nested steps, 75–78
organizing, 130
outlines, 70–75
overview, 7
pending, 55, 199
precision, 44
snippets, 14
splitting, 129
state passing, 122
vs. steps, 40
user interface connection,
142–146
wording, 44, 50–52, 114,
128, 137–141
stepdefs formatter, 195, 279
steps
failing, 56
feature-coupled, 149
imperative, 91, 93
matching, 40–50, 117
nested, 75–78
overview, 7
pending, 16, 55, 199
sleepy, 99–100
splitting, 129
vs. step definitions, 40
undefined, 54
steps method, 77, 281
stopping
Capybara, 262
the line, 105
web services, 217
storing in memory, 203, 216
.story extension, 81
--strict, 57, 199
strings
converting into numbers,
113, 117–120
doc strings, 78
interpolation, 77
multiple lines, 76
parsing, 211, 213
vs. regular expressions,
42
serializing, 162
stubs, 21
sub-folders, organizing with,
103
www.it-ebooks.info
subfolders, organizing with,
79–80
supermarket checkout application, 222–224
support code
booting up, 129
hooks, 147–150
user interface wrapping,
141–155
symptoms of problems, 85–89
synchronization, 158–160,
169–171, 266
syntax rules, see Gherkin
system setup, one-click, 102
system test environment, 100
T
tables
comparing with diff, 68
data tables, 64–69, 71,
77, 217, 254
Examples, 71–75
Rails, 233
Scenario Outline, 22
turning into arrays, 67
tags
@announce, 284, 286
filtering, 82, 193
hooks, 82, 147, 149,
258–261
limiting, 197
@no-clobber, 285
organizing with, 79–82,
103
partitioning with, 89, 103
WIP management, 197
--tags option, 193
TCP sockets and wire protocol, 297
TDD (Test-Driven Development)
automated acceptance
testing, 4
JavaScript, 262
teller application, see ATM
application
templates, feature descriptions, 31
terminology, see ubiquitous
language
Test Data Builders, 98, 102,
234
test doubles, 125, 154
test maintenance, 105
Index
Test-Driven Development,
see TDD (Test-Driven Development)
Test-Driven JavaScript Development, 262
Testbot, 89
testers, collaboration and,
101
testing, see acceptance testing; automated testing;
characterization tests; exploratory testing; unit testing
testing skills, 140
text editors, 302
Then keyword, 13, 30, 43
Three Amigos, 95–96
tic-tac-toe game, 66–69
timers, 264
Toyota, 105
transactions, cleaning
databases with, 181–185
transforms, 117–120, 129–
130
triangulation, 22
troubleshooting, see problems
truncation, cleaning databases with, 181, 185, 187
truth, source of, 7
U
U character in progress format-
ter, 194
ubiquitous language
advantages, 5
benefits, 95
context, 94
declarative style, 92
feature-coupled steps,
149
readability and, 50
revealing intention, 138
undefined steps, 54
unit testing, 4, 104
URLs
database resetting, 216
GET vs. POST, 252
HTTParty, 219
non-Ruby applications,
261
verifying page content,
252
usage formatter, 195
user input, Aruba, 288–291
user interface
building, 145, 150–154
creating records, 237
wrapping domain model,
133, 141–155
user stories, 81
user_path, 240
users, creating with Rails,
232–235
V
--verbose option, 196
verifying page content, 252
versions list, 303
visit(path) method, 239
W
\w shorthand, 49–50
walking skeleton, 22
Watchr, 241
Watir, 246
web applications
browsers and databases,
185
in-process testing, 201–
212
out-of-process testing,
201, 213–220
web interface, see user interface
WebKit, 259
www.it-ebooks.info
• 315
Webrat, 246, 267
When keyword, 13, 30, 43
whitespace
character shorthand, 49
JSON, 211
wildcards, 45–50
Wilk, Joe, 73
Windows
.bat file, 288
command prompt symbol, xx
console colors, 300
Ruby installation, 300
Service Manager, 166
--wip option, 197
WIP (Work in Progress), managing, 197
wire protocol, 295
wireframes, user interface,
145
withdrawals application,
see ATM application
word boundary shorthand, 49
word character shorthand,
49–50
Work in Progress (WIP), managing, 197
Working Effectively with
Legacy Code, 104, 222
World
about, 124
custom helper methods,
120–128
modules list, 124
Rack-Test, 207
state and, 122
Wrong, 60, 172
X
Xcode, 299
Y
YAML files, 198, 231
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